Methods for treating body tissue

ABSTRACT

Methods of treating body tissue including repairing defects in body tissue as well as augmenting body tissue. Body tissue defects are repaired by injecting a polymeric adhesive composition through an injector into the region of the defect and allowing the adhesive composition to cure to repair the defect or to form an implant that adheres to at least one surface tissue in the region of the defect. Body tissue is augmented by filling a defect void with a polymeric adhesive composition and allowing it to cure.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of application Ser. No. 10/117,931 filed Apr. 5, 2002, which is a continuation of application Ser. No. 09/451,206 filed Nov. 29, 1999, now U.S. Pat. No. 6,423,333, which is a continuation of application Ser. No. 08/642,246 filed May 2, 1996, now U.S. Pat. No. 6,033,654, which is a continuation-in-part of application Ser. No. 08/435,641 filed May 5, 1995, now U.S. Pat. No. 5,817,303, all of which are incorporated herein by reference.

INTRODUCTION TECHNICAL FIELD

The field of this invention is physiologically acceptable compositions for use as tissue adhesives and sealants.

BACKGROUND

In many situations, there is a need to bond separated tissues. Sutures and staples are effective and well established wound closure devices. However, there are surgical procedures where classical repair procedures are unsatisfactory, limited to highly trained specialists (e.g. microsurgery), or not applicable due to tissue or organ fragility, inaccessibility (e.g. endoscopy procedures), or fluid loss, including capillary “weeping”. Tissue adhesives and sealants have been developed to meet these needs. They may be used to seal or reinforce wounds that have been sutured or stapled, as well as finding independent use. The leading commercial products are fibrin glues and cyanoacrylates. However, both products have significant limitations which have prevented their widespread use.

Cyanoacrylates are mainly used for cutaneous wound closure in facial and reconstructive surgery. The appeal of cyanoacrylates is their speed of bonding, which is almost immediate, and its great bond strength. However, its speed of bonding can be a disadvantage, since glued tissue must be cut again in order to reshape it to the desired conformation. Additionally, it can only be used on dry substrates since its mode of action is through a mechanical interlock, limiting its use as a sealant, and it is relatively inflexible compared to surrounding tissue. Cyanoacrylates are also known to be toxic to some tissues and although it is not considered to be biodegradable, potential degradation products are suspected to be carcinogenic.

Fibrin glues comprising blood-derived fibrinogen, factor XIII and thrombin function primarily as a sealant and hemostat and have been used in many different surgical procedures within the body. They have been shown to be non-toxic, biocompatible and biodegradable. They are able to control excessive bleeding and decrease fibrosis. However, tissues bonded with fibrin cannot be subjected to even moderate tensile stress without rupturing the bond. It takes about three to ten minutes for an initial bond to develop, but requires about 30 minutes to several hours for full strength to develop. Depending upon the application, the product may also resorb too quickly. Use of recombinantly produced fibrinogen, factor XIII, thrombin and related components (e.g. fibrin, activated factor XIII) has not been demonstrated to improve the setting time or strength of fibrin glues. Fibrin glues derived from heterologous, human and animal, serum may provoke undesirable immune responses, and expose the patient to the potential risk of viral infection. Autologous fibrin glues may be impractical to obtain and use and may compromise patient safety.

There is, therefore, substantial interest in developing products which have the biocompatibility of fibrin glues, but which set more quickly and have enhanced strength. These products should be readily available, desirably from other than natural sources, be easily administered and capable of resorption over time.

Relevant Literature

Tissue adhesives are described in: Tissue Adhesives in Surgery, Matsumoto, T., Medical Examination Publishing Co., Inc. 1972 and Sierra, D. H., J. Biomat. App. 7:309-352, 1993. Methods of preparation of protein polymers having blocks of repetitive units are described in U.S. Pat. No. 5,243,038 and EPA 89.913054.3.

SUMMARY OF THE INVENTION

Polymeric compositions and methods for their use are provided, where the polymeric compositions are capable of in situ chemical crosslinking to provide novel crosslinked polymeric products, which have good mechanical and biological properties, as exemplified by strong adherent bonds to tissue. The compositions can be used in a variety of applications related to their physical, chemical and biological properties, to bond to separated tissue to provide at least one of the characterstics of a stable, flexible, resorbable bond.

DESCRIPTION OF THE SPECIFIC EMBODIMENTS

The subject compositions comprise high molecular weight recombinant polymers having one or a combination of repeating units related to naturally occurring structural proteins. Of particular interest are the repeating units of fibroin, elastin, collagen, and keratin, particularly collagen and combinations of fibroin and elastin. The polymers have functional groups which can be chemically crosslinked under physiological conditions with physiologically acceptable crosslinkers, so as to form a composition which has strong adherent properties to a variety of substrates, has strong mechanical properties in maintaining the joint between the substrates, and can be formulated to have good resorption properties.

Of particular interest, the subject compositions provide strongly adherent bonds to tissue to maintain separated tissue in a contiguous spatial relationship. The subject compositions may also be employed as sealants, where the compositions may serve to fill a defect void in tissue, to augment tissue mass or bond synthetic materials to tissues. The subject compositions may also serve as depots in vivo by being mixed with a drug composition, either when used as an adhesive for bonding tissue together or for other bonding or solely as a slow release source of the drug.

The functionalities for crosslinking may be all the same or combinations of functionalities and may include the functionalities of naturally occurring amino acids, such as amino, e.g. lysine, carboxyl, e.g. aspartate and glutamate, guanidine, e.g. arginine, hydroxyl, e.g. serine and threonine, and thiol, e.g. cysteine. Preferably, the functionality is amino (including guanidine).

The polymers will have molecular weights of at least about 15 kD, generally at least about 30 kD, preferably at least about 50 kD and usually not more than 250 kD, more usually not more than about 150 kD. The polymers will have at least two functionalities, more usually at least about four functionalities, generally having an equivalent weight per functionality in the range of about 1 kD to 40 kD, more usually in the range of about 3 kD to 20 kD, preferably in the range of about RD to 10 kD, there being at least 3, usually at least 6, functionalities available for crosslinking. If desired, one may use mixtures of polymers, where the polymers have combinations of functionalities or have different functionalities present e.g. carboxyl and amino, thiol and aldehyde, hydroxyl and amino, etc. Thus, depending upon the functionalities and the crosslinking agent, one can form amides, imines, ureas, esters, ethers, urethanes, thioethers, disulfides, and the like.

The individual units in the polymer may be selected from fibroin, GAGAGS (SEQ ID NO:01); elastin, GVGVP (SEQ ID NO:02); collagen GXX, where the X's may be the same or different, and at least 10 number % and not more than 60 number % of the X's are proline, and keratin, AKLK/ELAE (SEQ ID NO:3). The desired functionality may be substituted for one of the amino acids of an individual unit or be present as an individual amino acid or part of an intervening group of not more than about 30 amino acids, usually not more than about 16 amino acids. In the former case, within a block of repeats, one or more of the repeats is modified to introduce a crosslinking functionality which would otherwise not normally be present. Thus a valine may be replaced with a lysine, a glycine with an arginine, an alanine with a serine, and the like. In the latter case, there would be an intervening functionality between a block of repeat units, where the number of intervening functionalities would be based on the ranges indicated previously.

Of particular interest are copolymers, either block or random, preferably block, where in the case of elastin and fibroin, the ratio of elastin units to fibroin units is in the range of 16-1:1, preferably 8-1:1, where blocks may have different ratios. Normally, in block copolymers, each block will have at least two units and not more than about 32 units, usually not more than about 24 units. By substituting an amino acid in the unit with an amino acid having the appropriate functionality, one can provide for the appropriate number of functionalities present in the polymer or employ intervening groups between blocks.

The individual amino acid repeat units will have from about 3 to 30 amino acids, usually 3 to 25 amino acids, more usually 3 to 15 amino acids, particularly 3 to 12 amino acids, more particularly about 3 to 9 amino acids. At least 40 weight %, usually at least 50 weight %, more usually at least 70 weight %, of the protein polymer will be composed of segments of repetitive units containing at least 2 identical contiguous repetitive units. Generally repeat blocks will comprise at least 2, 4, 7 or 8 units, and combinations thereof, where copolymers are employed, where the unit which is modified with the crosslinking functionality is counted as a unit.

While for the most part, the polymers of the subject invention will have the active functionality of a naturally occurring amino acid in the chain of the polymer, if desired, pendent groups may be employed to provide the desired functionalities. For example, carboxyl groups may be reacted with polyamines so as to exchange a carboxyl functionality for a single amino or plurality of amino groups. An amino group may be substituted with a polycarboxylic acid, so that the amino group will be replaced with a plurality of carboxylic groups. A thiol may be replaced with an aldehyde, by reaction with an aldehydic olefin, e.g. acrolein, so as to provide for an aldehyde functionality. Other functionalities which may be introduced, if desired, include phosphate esters, activated olefins, e.g. maleimido, thioisocyanato, and the like. The functionalities may be greatly varied from those which naturally occur to provide opportunities for crosslinking. In some instances, this may be desirable to increase the number of functionalities per unit molecular weight, while not increasing the number of functionalities along the chain, for replacing one functionality with another, e.g. thiol with aldehyde, allowing for greater variation in the choice of crosslinking agent.

The crosslinking agent will normally be difunctional, where the functionalities may be the same or different, although higher functionality may be present, usually not exceeding four functionalities. Depending upon the particular functionalities available on the polymers, various crosslinking agents may be employed. The crosslinking agents will usually be at least about three carbon atoms and not more than about 50 carbon atoms, generally ranging from about 3 to 30 carbon atoms, more usually from about 3 to 16 carbon atoms. The chain joining the two functionalities will be at least one atom and not more than about 100 atoms, usually not more than about 60 atoms, preferably not more than about 40 atoms, particularly not more than about 20 atoms, ‘where the atoms may be carbon, oxygen, nitrogen, sulfur, phosphorous, or the like. The linking group may be aliphatically saturated or unsaturated, preferably aliphatic, and may include such functionalities as oxy, ester, amide, thioether, amino, and phosphorous ester. The crosslinking group may be hydrophobic or hydrophilic.

Various reactive functionalities may be employed, such as aldehyde, isocyanate, mixed carboxylic acid anhydride, e.g. ethoxycarbonyl anhydride, activated olefin, activated halo, amino, and the like. By appropriate choice of the functionalities on the protein polymer, and the crosslinking agent, rate of reaction and degree of cross linking can be controlled.

Various crosslinking agents may be employed, particularly those which have been used previously and have been found to be physiologically acceptable. Crosslinking agents which may be used include dialdehydes, such as glutaraldehyde, activated diolefins, diisocyanates such as, tetramethylene diisocyanate, hexamethylene diisocyanate, octamethylene diisocyanate, acid anhydrides, such as succinic acid dianhydride, ethylene diamine tetraacetic acid dianhydride, diamines, such as hexamethylene diamine, cyclo(L-lysyl-L-lysine), etc. The crosslinking agent may also contain unsymmetrical functionalities, for example, activated olefin aldehydes, e.g. acrolein and quinoid aldehydes, activated halocarboxylic acid anhydride, and the like. The crosslinking agents will usually be commercially available or may be readily synthesized in accordance with conventional ways, either prior to application of the adhesive or by synthesis in situ.

In some instances it may be desirable to react a physiologically acceptable second compound, which serves as a modifying unit, with a polyfunctional, usually bifunctional, compound to change the nature of the crosslinking. The addition of the second compound may be to enhance the rate of crosslinking, change the solubility properties of the crosslinker, enhance or reduce the strength of the crosslinked polymer, enhance or reduce the resorption rate, or provide for other physical, chemical or biological properties of interest. The polyfunctional second compound may be reacted with the crosslinking compound prior to reaction with the protein or concurrently with the reaction with the protein. Where the reaction is prior, the resulting crosslinking product will be physiologically acceptable and when concurrent, the polyfunctional second compound, the crosslinking compound and the resulting crosslinking product will be physiologically acceptable, when used in vivo. The ratio of the polyfunctional second compound to the crosslinking compound will generally be in the range of about 0.1-2:1, more usually in the range of about 0.11:1, depending on the reactivity of the polyfunctional second compound when the polyfunctional second compound and crosslinking agent are brought together, the number of crosslinks desired in the final protein composition, the size of the bridge between protein molecules, and the like.

The nature of the polyfunctional second compound may vary widely. The functional groups present may be the same or different from the functional groups present on the polymer, but will be reactive with the functionalities of the crosslinking compound. For example, the polyfunctional second compound may have amino and/or hydroxyl groups, where the protein has amino or hydroxyl functionalities. By employing a diisocyanate with a diol, diurethanes will be produced. Thus, the chain crosslinking the proteins will comprise 2 or more urethanes.

In many instances, the polyfunctional second compound will include an internal functionality that does not participate in the reaction, but provides various other characteristics to the crosslinking agent or the crosslinked protein product. Characteristics of interest include hydrophilicity, hydrolytic instability, sensitivity to enzymatic degradation, biocompatibility, shear strength, and the like. For the most part internal functionalities will comprise oxygen, sulfur and nitrogen atoms, such as ethers, carboxylic acid esters, including urethanes, amino groups, amides, ketones, dithiols and the like. To enhance the rate of resorption, ester groups are of interest, while to enhance hydrophilicity, the same groups maybe employed as well as ethers, such as polyoxyalkylene groups.

The polyfunctional second compound will generally have at least 2 carbon atoms and not more than 50 carbon atoms, usually not more than about 30 carbon atoms, desirably having not more than about 16 carbon atoms per heteroatom. Naturally occurring or synthetic bifunctional compounds may be employed. Illustrative compounds include lysine, arginine, di-(2′-aminoethyl) malonate, citrate, lysyl lysine, 2′-aminoethyl glycinate, O,N-diglycinyl ethanolamine, diethylene glycol diglycinate, cystine, and the like. To provide terminal amino groups, various low molecular weight amino acids may be used, particularly glycine and alanine bonded to an intervening difunctional compound, such as ethylene glycol, diethylene glycol, and tetraethylene glycol, propanediol, 1,4-butyn-2-diol, ascorbic acid, etc.

The subject compositions may be prepared prior to the use of the adhesive by combining the protein polymer and the crosslinking agent, where one or both may have extenders. The two compositions may be readily mixed in accordance with conventional ways, for example, using syringes which can inject the ingredients into a central reactor and the mixture mixed by drawing the mixture back into the syringes and moving the mixture back and forth. Alternatively, the two compositions may be dispensed simultaneously at the site of application. In some instances it may be desirable to allow the crosslinking agent to partially react with the protein prior to adding the polyfunctional second compound. Alternatively, one may mix the polyfunctional second compound with the protein prior to mixing with the crosslinking agent.

Usually, the polymer will be available as a dispersion or solution, particularly aqueous, generally the concentration of the protein polymer being in the range of about 50 mg to 1 g/ml, more usually from about 100 to 800 mg/ml. The solution may be buffered at a pH which enhances or retards the rate of crosslinking. Usually the pH will be in the range of about 2 to 12, more usually 8 to 11. Various buffers may be used, such as phosphate, borate, carbonate, etc. The cation can have an effect on the nature of the product, and to that extent, the alkali metals potassium and sodium, are preferred. The protein composition will generally be about 5 to 40, more usually from about 5 to 20, preferably from about 10 to 20 weight %, to provide for a composition which may be readily handled, will set up within the desired time limit, and the like. The buffer concentration will generally be in the range of about 50 to 500 mM. Other agents may be present in the protein solution, such as stabilizers, surfactants, and the like. If the polyfunctional second compound is present, its concentration will be determined in accordance with its ratio to the crosslinking agent and the polymer.

The ratio of crosslinking agent to polymer will vary widely, depending upon the crosslinking agent, the number of functionalities present on the polymer, the desired rate of curing, and the like. Generally, the weight ratio of polymer to crosslinking agent will be at least about 1:1 and not greater than about 100:1, usually not greater than about 50:1, generally being in the range of about 2 to 50:1, but in some instances may not be more than 30:1. The equivalent ratio of protein to crosslinking agent will generally be in the range of about 0.1-1:3, more usually in the range of about 0.5-2:2. Considerations in selecting the protein-crosslinking agent equivalent ratio will be the rate of setup, reactivity of the crosslinking agent, relative solubility of the crosslinking agent in the mixture, physiological properties of the crosslinking agent, desired degree of stability of the crosslinked product, and the like.

If desired, various extenders or extending agents may be used, particularly naturally occurring proteins. Such extenders will usually not exceed 50 weight percent of the composition, generally not exceeding about 20 weight percent, more usually not exceeding about 10 weight percent. Extenders which may be employed include, but are not limited to: synthetic polymers, both addition and condensation polymers, both protein and non-protein, such as polylactides, polyglycolides, polyanhydrides, polyorthoesters, polyvinyl compounds, polyolefins, polyacrylates, polyethylene glycol, polyesters, polyvinyl alcohol, polyethers, copolymers and derivatives thereof, and naturally occurring polymers, such as proteins and nonproteins, including collagen, fibrinogen, fibronectin, laminin, keratin, chitosan, heparin, dextran, alginates, cellulose, glycosoaminoglycans, hyaluronic acid, polysaccharides, derivatives thereof, and the like. The extenders may modulate the setting time and provide for desirable physical or physiological properties of the adhesive.

Based on the lap shear tensile strength test described in the experimental section, within 30 minutes, usually within 15 minutes, more usually within 5 minutes, the lap shear tensile strength will be at least 100, preferably at least about 250, more preferably at least about 300, usually not exceeding about 4000, more usually not exceeding about 3000 g/cm².

The subject compositions may be applied to the tissue in any convenient way, for example by using a syringe, catheter, cannula, manually applying the composition, spraying or the like. The subject compositions may be applied to the tissue prior to or during the time the tissue segments are held in contiguous relationship. The subject compositions will rapidly develop substantial shear strength, so as to maintain the tissue in proximity. In some situations there will be an interest in having the composition decompose after some reasonable period of time, usually at least one week and generally not more than about four weeks.

Tissues of interest include vascular vessels such as an artery, vein or capillary, muscel, nerve, organs, e.g. liver, spleen, etc., lung, dura, colon, and the like.

In addition to their use as adhesives, the subject compositions may be used to seal or fill defects, e.g. voids or holes, in tissue, and therefore find use as sealants. Thus, the compositions may serve to stop or staunch the flow of fluid, e.g. blood, through ruptured vessels, e.g. arteries, veins, capillaries and the like. In using the subject compositions as sealants, the composition will be applied, as described above, at the site of the defect, whereby it will set and seal the defect. The compositions may be injected into normal or abnormal tissues to augment the tissue mass, e.g. dermis.

The subject compositions may also find use in the formation of articles of manufacture, by themselves or in combination with other materials. In one application, articles may be produced for use internally to a mammalian host, where there is an interest in biocompatibility, reabsorption rate, ability to vascularize, tissue adhesive and/or bonding capability, and the like. Various articles can be prepared, such as gels, films, threads, coatings, formed objects such as pins and screws, or injectable compositions which are flowable, where the injectable composition may set up and bond or seal tissues, form a depot for a drug, augment tissue or be a filler, coating or the like. The formed objects may be prepared in accordance with conventional ways, such as molding, extrusion, precipitation from a solvent, solvent evaporation, and the like. The flowable depot can be obtained by using a molecular dispersion, fine particles in a medium saturated with a polymer, using a melt, where the melting temperature may be achieved by adding physiologically acceptable additives, and the like.

The articles may find use in a variety of situations associated with the implantation of the article into a mammalian host or the application of the article to the surface of a mammalian host, e.g. wound healing, burn dressing, etc. Those situations, where the performance of the articles may be retained for a predetermined time and replaced by natural materials through natural processes, desirably employ materials which will be resorbed after having fulfilled their function in maintaining their role until the natural process has reestablished a natural structure. Thus, the compositions may find use in holding tissue together, covering tissue, encapsulating cells for organs, providing a coating that cells can invade and replace the composition with natural composition, e.g., bone, soft tissues and the like.

To enhance the rate of curing of the polymeric composition, the composition may be partially prepolymerized. When prepolymerized, the polymer will usually have at least about 3% of the total number of crosslinks and not more than about 75% of the total number of crosslinks, as compared to completion of the crosslinking action. The number of crosslinks should allow the resulting product to be workable and provide sufficient time prior to set up for it to be manipulated and used. Alternatively, one may react the functional groups with an excess of the crosslinking reagent, so that the effect is to substitute the functionality of the protein with the functionality of the crosslinking agent. The protein with the substituted functionality may then be used to crosslink protein with the original functionality or with a polyfunctional second compound.

The subject compositions may also be used as depots to provide for a relatively uniform release of a physiologically active product, e.g., a drug. The drug may be mixed with a subject composition at an appropriate concentration prior to crosslinking. As the crosslinked polymer is degraded, the drug will be released due to diffusion as well as erosion of the external surface of the depot. By controlling the form or shape of the depot, the degree of crosslinking, the concentration of the drug and the like, a physiologically therapeutic level of the drug may be maintained over extended periods of time. The period required for absorption can be as short as 0.5 day and may exceed 4, 6 or 8 weeks or more, depending upon the particular composition and the application.

The protein polymer compositions may be prepared in accordance with conventional ways. See, for example, U.S. Pat. No. 5,243,038, which disclosure is incorporated herein by reference. Briefly, sequences may be synthesized comprising a plurality of repeating units, where complementary sequences result in dsDNA having overhangs. A series of dsDNA molecules may be prepared and stepwise introduced into a cloning vector as the gene for the protein is constructed. A monomer can be obtained in this way, which may be sequenced to ensure that there have been no changes in the sequence, followed by multimerization of the monomer, cloning and expression. For further details, see the above indicated patent.

The following examples are offered by way of illustration and not by way of limitation.

EXPERIMENTAL Example 1

Methods

The construction of synthetic DNA and its use in large polypeptide synthesis is described in U.S. Pat. No. 5,243,038; PCT/US89/05016 and PCT/US92/09485, the disclosures of which are herein incorporated by reference. Modifications to these methods and additional methods used are described below.

1. Use of Filters and Columns for DNA Purification

A. Ultrafree®-Probind filter unit (“Probind”, Millipore): the DNA containing solution was applied to the filter unit and spun at 12,000 RPM for 30 seconds in a Sorvall Microspin 24S.

B. Microcon-30 filter (Amicon): the DNA containing solution was washed by applying to the filter and exchanging twice with H2O by spinning at 12,000 RPM for 6 minutes in a microfuge.

C. Bio-Spin 6 column (“Bio-Spin”, BioRad): Salts and glycerol were removed from the DNA solution by applying to the column, previously equilibrated in TEAB (triethyl ammonium bicarbonate pH 7.0), and spinning in a Sorvall RC5B centrifuge using an HB4 rotor at 2,500 RPM for 4 minutes.

2. Phosphatase Treatment of DNA

Phosphatase treatment of DNA was also performed by resuspending ethanol precipitated DNA from the restriction enzyme digest in 20 mM Tris-HCl pH 8.0, 10 MM MgCl₂ to a final DNA concentration of 20 μg/ml. Shrimp Alkaline Phosphatase (SAP) was added at 2 U/μg of DNA and the mixture was incubated at 37° C. for one hour, heat inactivated for 20 minutes at 65° C. and then passed through a Probind filter and subsequently a Bio-Spin column.

3. Preparative Agarose Gel Electrophoresis

For agarose ligation, the buffer used was 1×TAE (50 mM Tris-acetate, pH 7.8).

4. Agarose DNA Ligation

The agarose was melted at 65° C., the temperature was then lowered to 37° C. and ligation buffer (5×=100 mM Tris-HCl, pH 7.5, 50 MM MgCl₂, 50 mM DTT, 1 mM ATP) was added; the tube was then placed at room temperature and ligase was added (1000 units T4 DNA ligase (NEB)). The reaction volume was usually 50 μl. The reaction was incubated at 15° C. for 16-18 hours.

5. Agarose DNA Purification Using an Ultrafree®-MC Filter Unit

This procedure can be used for agarose slices up to 400 μl in size. After agarose gel electrophoresis, the DNA is visualized by ethidium bromide staining and the agarose block containing the DNA band of interest is excised. The agarose is then frozen at −20° C. for 1 hour, then quickly thawed at 37° C. for 5 minutes. The agarose is then thoroughly macerated. The pieces are then transferred into the sample cup of the filter unit and spun at 5,000×g in a standard microfuge for 20 minutes. The agarose is then resuspended in 200 μl of Tris-EDTA, or other buffer, and incubated at room temperature for 30 minutes to allow for elution of additional DNA from the gel. The mixture is then centrifuged for an additional 20 minutes at 10,000 RPM. The DNA is, at this point, in the filtrate tube separated from the agarose fragments and ready for subsequent DNA manipulations.

6. Preparation of Antibody to Artificially Synthesized Peptides

The same procedures were used as described in U.S. Pat. No. 5,243,038, PCT/US89/05016 and PCT/US92/09485.

7. Immunoblotting of Proteins in Gels

An alternative to the ¹²⁵I-Protein A detection method was used. This method relied on a chemiluminescent signal activated by horseradish peroxidase (HRP). The chemiluminescent reagents are readily available from several suppliers such as Amersham and DuPont NEN. The western blot was prepared and blocked with BLOTTO. A number of methods were used to introduce the HRP reporter enzyme including, for example, a hapten/anti-hapten-HRP, a biotinylated antibody/streptavidin-HRP, a secondary reporter such as a goat or mouse anti-rabbit IgG-biotinylated/streptavidin-HRP, or a goat or mouse-anti rabbit IgG-HRP. These reagents were bought from different sources such as BioRad or Amersham and occasionally biotinylated antibodies were prepared in our laboratory using Biotin NHS from Vector Laboratories, Burlingame, Calif. (Cat. #SP-1200) following the procedure accompanying the product. The following is an example of a procedure used to detect the expression of protein polymers.

The blot was placed in 15 ml of BLOTTO solution containing biotinylated goat anti-rabbit IgG (BioRad) diluted in BLOTTO (1:7500) and gently agitated for 2 hours at room temperature. The filter was then washed for 30 minutes with 3 changes of TSA (50 mM Tris-HCl pH 7.4, 0.9% NaCl, 0.2% sodium azide) and then for 5 minutes each in TBS with 0.1% TWEEN®20. The blot was then incubated for 20 minutes at room temperature with gentle rotation, in 20 ml of TBS (100 mM Tris Base, 150 mM NaCl, pH 7.5) HRP-Streptavidin (Amersham) diluted 1:1000 in TBS with 0.1% Tween 20. The blot was then washed three times for 5 minutes each in TBS with 0.3% Tween 20 and then three times for 5 minutes each in TBS with 0.1% Tween 20. The blot was then incubated for 1 minute with gentle agitation in 12 ml of development solutions #1 an #2 (Amersham) equally mixed. The blot was removed from the development solution and autoradiographed.

8. Protein Expression Analysis

An overnight culture which had been grown at 30° C. was used to inoculate 50 ml of LB media contained in a 250 ml flask. Kanamycin was added at a final concentration of 50 μg per ml and the culture was incubated with agitation (200 rpm) at 30° C. When the culture reached an OD₆₀₀, of 0.8, 40 ml were transferred to a new flask prewarmed at 42° C. and incubated at the same temperature for approximately 2 hours. The cultures (30° and 42°) were chilled on ice and OD₆₀₀. was taken. Cells were collected by centrifugation and then divided in 1.0 OD₆₀₀ aliquots and used to perform western analysis using the appropriate antibodies.

9. Amino Acid Analysis

Amino acid derivatives were analyzed by reverse phase HPLC using a Waters 600E system.

10. Peptide Synthesis

Synthetic peptides were also prepared on a Rainin/Protein Technologies PS3 FMOC peptide synthesizer. Both the synthesis and cleavage were accomplished using the methods supplied by the manufacturer in the instrument manual.

11. In Vitro DNA Synthesis

The β-cyanoethyl phosphoramidites, controlled-pore glass columns and all synthesis reagents were obtained from Applied Biosystems, Foster City, Calif. Synthetic oligonucleotides were prepared by the phosphite triester method with an Applied Biosystems Model 381A DNA synthesizer using a 10-fold excess of protected phosphoramidites and 0.2 mole of nucleotide bound to the synthesis support column. The chemistries used for synthesis are the standard protocols recommended for use with the synthesizer and have been described (Matteucci et al., J. Amer. Chem. Soc., 103:3185-3319 (1981)). Deprotection and cleavage of the oligomers from the solid support were performed according to standard procedures as provided by Applied Biosystems. The repetitive yield of the synthesis as measured by the optical density of the removed protecting group as recommended by Applied Biosystems was greater than 97.5%.

The crude oligonucleotide mixture was purified by preparative gel electrophoresis as described by the Applied Biosystems protocols in Evaluating and Isolating Synthetic Oligonucleotides, 1992 (Formerly: User Bulletin 13, 1987). The acrylamide gel concentration varied from 10 to 20% depending upon the length of the oligomer. If necessary, the purified oligomer was identified by UV shadowing, excised from the gel and extracted by the crush and soak procedure (Smith, Methods in Enzymology, 65:371-379 (1980)).

For DNA synthesis of oligonucleotides longer then 100 bases, the synthesis cycle was changed from the protocol recommended by Applied Biosystems for the 381A DNA synthesizer. All the reagents used were fresh. All the reagents were supplied by Applied Biosystems except for the acetonitrile (Burdick and Jackson Cat #017-4 with water content less then 0.001%) and the 2000 A pore size column (Glen Research). Due to the length of the oligo, interrupt pauses had to be inserted during the synthesis to allow changing the reagent bottles that emptied during synthesis. This interrupt pause was done at the cycle entry step and the pause was kept as short as possible. The washes after detritylation by TCA, through the beginning of each synthesis cycle, were increased from about 2× to 3× over the recommended time. The time allocated for the capping was also increased to limit truncated failure sequences. After the synthesis the deprotection was done at 55° C. for 6 hours. After desalting the synthesized DNA was amplified using PCR.

12. Sequencing of DNA

Storage and analysis of data utilized software from DNA Strider, DNA Inspection Ile or DNAid for Apple Macintosh personal computer.

13. Dideoxy DNA Sequencing of Double Stranded Plasmid DNA

As described in U.S. Pat. No. 5,243,038, plasmid DNA was prepared on a small scale. Primers were synthesized using a DNA synthesizer and were annealed to the plasmid DNA following the procedure described for M13 sequencing. The sequencing reactions were done using Sequenase (United States Biochemicals) and the conditions were as recommended by the supplier. All sequences were run on polyacrylamide gels.

14. PCR Amplification

The PCR reaction was performed in a 100 μl volume in a Perkin Elmer thinwalled Gene Amps” reaction tube. Approximately 1 μM of each primer DNA was added to 1×PCR buffer (supplied by Perkin Elmer as 10× solution), 200 μM of each dNT, 5 U AmpliTaq, and several concentrations of the target DNA. Amplification was performed in a Perkin Elmer DNA Thermal cycler model 480 for 30 cycles with the following step cycles of 12 minutes each: 95° C., 62° C., and 72° C. Aliquots from the different reactions were analyzed by agarose gel electrophoresis using 1.5% low melting point agarose in 0.5×TA buffer. The reaction mixtures that gave the desired band were pooled and spun through a Probind filter to remove the AmpliTaq enzyme, then a Microcon-30 filter and a Bio-Spin column. The DNA was then concentrated in vacuo.

15. Diamine Synthesis

2-Aminoethyl Glycinate:

Concentrated sulfuric acid (9.90 g, 0.101 mole) was diluted into 10 ml, of water. Glycine (7.50 g, 0.100 mole), 2-aminoethanol (6.10 g, 0.100 mole) and the diluted sulfuric acid were placed in a 250 mL, 3-neck, round bottom flask fitted with a stopper, a mechanical stirrer, a heating mantle, and a Dean-Stark water trap. The contents of the apparatus were protected from atmospheric moisture with a nitrogen blanket. Toluene (100 mL) was added and the contents of the apparatus refluxed until no further evolution of water occurred. The apparatus was disassembled and the toluene was decanted before the flask was connected to a vacuum line to strip off toluene entrapped in the reaction mass. The product was used without further purification. The FTIR spectrum of the reaction product shows strong carbonyl adsorptions at 736 cm⁻¹ and 1672 cm⁻¹. The reaction product is estimated to be an approximately 4:1 mixture of 2-aminoethyl glycinate and N,O-diglycyl ethanolamine by comparison with the spectra of ethyl glycinate hydrochloride and glycyl glycine hydrochloride.

Cholinyl Lysinate:

Concentrated sulfuric acid (11.40 g, 0.120 mole) was diluted into water (10 mL). Lysine monohydrochloride (13.69 g, 0.075 mole), choline chloride (10.47 g, 0.075 mole), and the diluted sulfuric acid was placed into a 250 mL 1-neck round bottom flask fitted with a magnetic stirring bar, heated in a thermostatted oil bath, and connected to a vacuum line. Vacuum was gradually applied to the flask and then heat gradually increased in order to remove volatiles into a trap cooled in liquid nitrogen. The reaction was terminated when the bath temperature reached 110° C. and the pressure decreased to 0.024 mm-Hg. The product is homogeneous by thin layer chromatography (cellulose, acetic acid/acetonitrile/water 5:65:30 v/v/v, developed with ninhydrin spray, Rf=0.25). The product was used directly.

1,3-Propanediyl Diglycinate:

Concentrated sulfuric acid (10.78 g, 0.110 mole) was diluted into water (10 mL). 1,3-Propanediol (7.61 g, 0.100 mole), glycine (15.0 g, 0.200 mole), and the diluted sulfuric acid were placed in a 250 mL, 3-neck, round bottom flask fitted with a stopper, a mechanical stirrer, a thermostatted oil bath, and a Dean-Stark water trap. The contents of the apparatus were protected from atmospheric moisture with a nitrogen blanket. Toluene (100 mL) was added, the oil bath thermostatted at 130° C., and the contents of the apparatus refluxed until no further evolution of water occurred (ca. 9 hours). The apparatus was disassembled and the toluene decanted. The reaction mass was dissolved in water (29 mL) by stirring at room temperature. Upon cooling to −20° C. for 18 hours, the solution deposits fine white crystals which are removed by filtration. The filtrate is poured into methanol (250 mL), precooled to 3° C., to deposit a semi-solid paste. The supernatant was decanted, and the paste triturated in several portions in a mortar and pestle with methanol (50 mL) to yield a granular solid (12.55 g). A sample of solid (9.19 g) was boiled with methanol (18.4 mL) plus water (7.9 mL), filtered while hot, and allowed to crystallize at 4° C. for 18 hours. The precipitate was filtered while cold, compacted on the funnel under a dam, rinsed with methanol, acetone, and air dried, to yield a white crystalline solid (6.89 g). A sample of this material was titrated with aqueous KOH using a pH meter. The apparent equivalent weight per amine is 201 g/mole; an acidic contaminant with an apparent equivalent weight of 601 g/mole was also present. The FTIR shows a single carbonyl absorption at 1744 cm⁻¹

16. Fermentation Conditions

The fermentors used for the expression of protein polymers were usually a 15 L MBR, 10 L working volume, or a 13 L Braun Biostat E, 8.5 L working volume. The choice of the fermentor and its size is not critical. Any media used for the growth of E. coli can be used. The nitrogen source ranged from NZAmine to inorganic salts and the carbon source generally used was glycerol or glucose. All fermentations were done with the appropriate selection conditions imposed by the plasmid requirements (e.g. kanamycin, ampicillin, etc.). The fermentation method used to express protein polymers in E. coli was the fed-batch method. This is the preferred method for the fermentation of recombinant organisms even if other methods can be used.

The fed-batch method exploits the stage of cell growth where the organisms make a transition from exponential to stationary phase. This transition is often the result of either depletion of an essential nutrient or accumulation of a metabolic byproduct. When the transition is the result of nutrient depletion, the addition of nutrients to the system causes cell division to continue. One or more essential nutrients can incrementally be added to the fermentation vessel during the run, with the net volume increasing during the fermentation process. The result is a controlled growth rate where biomass and expression levels can be optimized. When the cell number in the culture has reached or is approaching a maximum, protein polymer production is induced by providing an appropriate physical or chemical signal, depending upon the expression system used. Production will then continue until the accumulated product reaches maximum levels (Fiestcliko, J., and Ritch, T., Chem. Eng. Commun. 1986, 45:229-240; Seo, J. H.; Bailey, J. E., Biotechnol. Bioeng. 1986, 28:1590-1594).

Example 2

Construction of SELP8K, SELP8E and CLP6

Polymers were prepared designated SELP8K and SELP8E, which are characterized by having functional groups for cross-linking. The construction of these polymers is described below starting from the previous gene monomer, SELPO (see U.S. Pat. No. 5,243,038, pSY1298).

SELP8K and SELP8E Amino Acid Monomer Sequence Design: (SEQ ID NO:04) SELP8K MONOMER (GAGAGS)₄ (GVGVP)₄ GKGVP (GVGVP)₃ (SEQ ID NO:05) SELP8E MONOMER (GAGAGS)₄ (GVGVP)₄ GEGVP (GVGVP)₃ SELP8 Construction

Plasmid pSY1378 (see U.S. Pat. No. 5,243,038) was digested with Banl REN, purified using agarose gel electrophoresis followed by NACS column, and the DNA was then ethanol precipitated in 2.5 M ammonium acetate and ligated with pPT0134 (See PCT\US92\09485) previously digested with Fold REN, phenol/chloroform extracted and ethanol precipitated.

The products of the ligation mixture were transformed into E. coli strain HB 101. Plasmid DNA from transformants was purified and analyzed by digestion using Nrul and XmnI RENs. Plasmid pPT0255 containing the desired restriction pattern was obtained and was used for subsequent constructions.

Plasmid DNA pPT0255 was treated with Cfr10I REN followed by RNAse. The digestion fragments were separated by agarose gel electrophoresis, the DNA was excised and self-ligated. The products of the ligation mixture were transformed into E. coli strain HB 101. Plasmid DNA from transformants was purified and analyzed by digestion using NaeI and Stal RENs. Plasmid pPT0267 containing the desired deletion was used for subsequent constructions.

Two oligonucleotide strands as shown in Table 1 were synthesized and purified as described in Example 1. TABLE 1 5′-CTGGAGCGGGTGCCI′GCATGTACATCCGA (SEQ ID NO:06) GT-3′ 3′-CCGAGACCTCGCCCACGGACGTACATGTAG (SEQ ID NO:07) GCTCA-5′

The two oligonucleotide strands were annealed and ligated with the DNA of plasmid pPT0267 which had been previously digested with Banll and Scal RENs, and purified by agarose gel electrophoresis followed by NACS column.

The products of this ligation reaction were transformed into E. coli strain HB101. Plasmid DNA from transformants was purified and digested with Dral. Plasmid DNA from two clones that gave the correct digestion pattern was sequenced. One plasmid DNA, designated pPT0287, was found to be correct and chosen for further constructions.

Plasmid DNA pSY1298 (see U.S. Pat. No. 5,243,038) was digested with BanlI REN, and the SELPO gene fragment was purified by agarose gel electrophoresis followed by NACS and then ligated to pPT0287 digested with Banll. The enzyme was then removed using phenol/chloroform extraction and ethanol precipitation.

The products of the ligation mixture were transformed into E. coli strain HB101. Plasmid DNA from transformants was purified and analyzed by digestion using Dral REN. Plasmid DNA from the clones showing the correct restriction pattern was further digested with BanlI, Ahall and Stul RENs. Plasmid pPT0289 contained the desired SELP8 monomer sequence (see Table 2). TABLE 2 SELP8 Gene Monomer Sequence (SEQ ID NOS: 08 & 09) BanI                                    BanII GGTGCCGGTTCTGGA   GCTGGCGCGGGCTCTGGA   GTAGGTGTGCCAGGT CCACGGCCAAGA   CCTCGACCGCGCCCCAGA   CCTCATCCACACGGTCCA G     A     G     S     G     A     G     A     C     S    G     V     G     V     P     G GTAGGA   GTTCCGGCTGTAGGCGTTCCGGGA   GTTGGTGTACCTGGAGTG CATCCTCAAGGCCCACATCCGCAAGGCCCTCAACCACATGGA   CCTCAC V     G     V     P     G     V     G     V     P     G    V     G     V     P     G     V                                           Smal GGTGTTCCAGGCGTAGGTGTGCCCGGG   GTAGGA   GTACCACOGGTAGGC CCA CAACGI CCG CAT CCA CAC CCC CCC CAT CCI CAT GCT CCC CAT CCG G     V     P     G     V     G     V     P     G     V    G     V     P     G     V     G                BanII GTCCCTGGA   GCCGGTGCTGGTAGCGGCGCAGGCGCGGGCTCTGGA   GCG CAGGGA   CCTCGCCCACGACCATCGCCGCGTCCGCGCCCGAGA   CCTCGC V     P     G     A     G     A     G     S     G     A    G     A     G     S     G     A

Construction of SELP8K and SELP8E Gene Monomers

One oligonucleotide strand coding for a portion of the SELP8 gene monomer was synthesized with a single base polymorphism at position 90. The use of both adenine and guanidine at this position produced oligonucleotides from a single synthesis that encoded the amino acids lysine and glutamic acid (see Table 3). The synthesis was conducted using an Applied Biosystems DNA synthesizer model 381A and a 2000A synthesis column supplied by Glen Research. During the synthesis the required interrupt-pauses for bottle changes were minimized. After the synthesis the 202 base DNA fragment was deprotected and cleaved from the column support by treatment in 30% ammonium hydroxide at 55° C. for 6 hours. TABLE 3 (SEQ ID NO:10) 5′-ATGGCAGCGAAAGGGGACCGGGCTCTGGTGTTGGAGTGCCAGGTGTC GGTGTTCCGGGTGTAGGCGTTGGTGTACCTGGA(A/G)AAGGTGTTCCGG GGGTAGGTGTGCCGGGCGTTGGAGTACCAGGTGTAGGCGTCCCGGGAGCG GGTGCTGGTAGCGGCGCAGGCGCGGGCTCTTTCCGCTAAAGTCCTGCCGT -3′

Two additional DNA strands were used as primers for PCR amplification. The two strands were: (SEQ ID NO:11) 1. 5′-AAGAAGGAGATATCATATGGCAGCGAAAGGGGACC-3′ (SEQ ID NO:12) 2. 5′-CGCAGATCTTTAAATTACGGCAGGACTTTAGCGGAAA-3′

The PCR reaction was carried out and the reaction product was purified as described in Example 1.

The DNA was resuspended and digested with BanlI REN as described in Example 1. The digested DNA was then separated by low-melting agarose gel electrophoresis and ligated with pPT0289 previously digested with Banll RENs and purified by NACS column. The products of the ligation reaction were transformed into E. coli strain HB 101. Plasmid DNA from isolated transformants was purified and analyzed by digestion using ApaLI and EcoNI RENs. Plasmid DNA from the clones showing the correct restriction pattern were further analyzed by digestion using Asp700 REN to distinguish between clones encoding a lysine or glutamic acid at the polymorphic position. Plasmid DNA from clones containing each of the polymorphs was purified and analyzed by DNA sequencing. Plasmid pPT0340 contained the desired SELP8K monomer sequence (see Table 4) and pPT0350 contained the desired SELP8E monomer sequence. TABLE 4 SELP8K Gene Monomer Sequence (SEQ ID NO: 13 &14) BanI                                             BanII GGTGCCGGTTCTGGA   GCTGGCGCGGGCTCTGGTGTTGGA   GTGCCAGGT CCACGGCCAAGA   CCTCGACCGCGCCCGAGA   CCACAACCTCACGGTCCA G     A     G     S     G     A     G     A     G     S    G     V     G     V     P     G          EcoNI GTCGGTGTTCCGGGTGTAGGCGTTCCGGGA   GTTGGTGTACCTGGA   AAA CAGCCACAAGGCCCACATCCGCAAGGCCCTCAACCACATGGA   CCTTTT V     G     V     P     G     V     G     V     P     G    V     G     V     P     G     K GGTGTTCCGGGG   GTAGGTGTGCCGGGCGTTGGA   GTACCAGGTGTAGGC CCACAAGGCCCCCATCCACACGGCCCGCAACCTCATGGTCCACATCCG G     V     P     G     V     G     V     P     G     V    G     V     P     G     V     G.       SmalBanII GTCCCGGGA   GCGGGTGCTGGTAGCGGCGCAGGCGCGGGCTCTGGA   GCG CAGGGCCCTCGCCCACGACCATCGCCGCGTCCGCGCCCGAGA   CCTCGC V     P     G     A     G     A     G     S     G     A    G     A     G     S     G     A

SELP8K Polymer Construction

Plasmid DNA from pPT0340 was digested with Banl REN and the digestion fragments were separated by agarose gel electrophoresis. The SELP8K gene fragment, 192 bp, was excised and purified by NACS column. The purified fragment was ligated with plasmid pPT0317 which had been digested with Banl REN, passed through a Millipore Probind and a Bio-Spin 6 column. The DNA was then treated with shrimp alkaline phosphatase (SAP) as described in Example 1.

The products of this ligation reaction were transformed into E. coli strain HB101. Transformants were selected for resistance to kanamycin. Plasmid DNA from individual transformants was purified and analyzed for increase size due to SELP8K monomer multiple DNA insertion. Several clones were obtained with insert sizes ranging from 200 by to approximately 7 kb. Clones containing from 6 to 32 repeats, were used for expression of the SELP8K protein polymer (pPT0341, pPT0343, pPT0344, pPT0345 and pPT0347).

SELP8K Expression Analysis

An overnight culture which had been grown at 30° C. was used to inoculate 50 ml of LB media contained in a 250 ml flask. Kanamycin was added at a final concentration of 50 μg per ml and the culture was incubated with agitation (200 rpm) at 30° C. When the culture reached an OD600 of 0.8, 40 ml were transferred to a new flask prewarmed at 42° C. and incubated at the same temperature for approximately 2 hours. The cultures (30° and 42°) were chilled on ice and OD600 was taken. Cells were collected by centrifugation and divided in 1.0 OD600 aliquots and used to perform western analysis using anti-SLP antibody.

E. coli strain HB101 containing plasmids pPT0341, pPT0343, pPT0344, pPT0345 and pPT0347 were grown as described above. The proteins produced by these cells were analyzed by Western blot for detection of proteins reactive to SLP antibodies. Each clone produced a strongly reactive band. The apparent molecular weights of the products ranged from approximately 35 kD to greater than 250 kD. Strain pPT0345 produced an SLP antibody reactive band of apparent molecular weight 80,000. The expected amino acid sequence of the SELP8K polymer encoded by plasmid pPT0345 is shown below. (SEQ ID NO:15) pPT0345    SELP8K         884 AA         MW 69,772 MDPVVLQRRDWENPGVTQLNRLAAHPPFASDPMGAGSGAGAGS ((GVGVP)₄   GKGVP  (GVGVP)₃     (GAGAGS)₄]₃₂ (GVGVP)₄  GKGVP  (GVGVP)₃       (GAGAGS)₂ GAGAMDPGRYQDLRSHHHHHH

SELP8K Purification

SELP8K was produced in E. coli strain pPT0345 by fermentation. The product was purified from the cellular biomass by means of cellular lysis, clearance of insoluble debris by centrifugation, and affinity chromatography. The purified product was analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis, immunoreactivity with a polyclonal antisera which reacts with silk-like peptide blocks (SLP antibody), and amino acid analysis. A protein band of apparent molecular weight 80,000 was observed by amido black staining of SDS-PAGE separated and transferred samples and the same band reacted with the SLP antibody on Western blots. As expected, amino acid analysis (shown in Table 5) indicated that the product was enriched for the amino acids glycine (43.7%), alanine (12.3%), serine (5.3%), proline (11.7%), and valine (21.2%). The product also contained 1.5% lysine. The amino acid composition table below shows the correlation between the composition of the purified product and the expected theoretical compositions as deduced from the synthetic gene sequence. TABLE 5 Amino Acid Analysis of Purified SELP8K Actual % Theoretical % Amino Acid pmoles composition composition Ala 1623.14 12.3 12.2 Asx 122.20 0.9 0.8 Glx nd nd 0.4 Phe 58.16 0.4 0.1 Gly 5759.31 43.7 41.5 His 46.75 0.4 0.8 Ile 43.87 0.3 0 Lys 198.21 1.5 1.5 Leu 39.54 0.3 0.5 Met 36.01 0.3 0.3 Pro 1534.21 11.7 12.4 Arg 70.84 0.5 0.6 Ser 703.83 5.3 6.1 Thr nd nd 0.1 Val 2797.47 21.2 22.4 nd = none detected

CLP6 Preparation

CLP6 was prepared as described in PCT/US92/09485 using strain pPT0246 (CLP6 referred to as DCP6). The protein polymer was purified in multigram quantities using standard protein purification, extraction, and separation methods. The lyophilized product was a white, spongy material, extremely soluble in water. (SEQ ID NO:16) CLP6 pPT0246        1,065 AA     MW 85,386 MDPVVLQRRDWENPGVTQLNRLAAHPPFASDPM [(GAHGPAGPK)₂(GAQGPAGPG)₂₄(GAHGPAGPK)₂]₄ GAMDPGRYQLSAGRYHYQLVWCCK

Example 3 The Construction of SELPOK Polymers

Polymer Design Elements

The copolymer structure of SELP8K consists of silk-like blocks (SLP block) and elastin-like blocks (ELP block) in the following sequence: [(SLP block)4 (ELP block)₈]. Additional polymers were designed to have different resorption and solution properties by adjusting their silk-like to elastin-like block lengths while maintaining their adhesive properties. SELPOK contains half the length of crystallizable silk-like blocks than SELP8K while maintaining the dispersion frequency with respect to the elastin-like segments.

Polymers with intervening sequences to promote in vivo resorption through proteolytic cleavage by collagenase (92 kd) and cathepsins were also designed. SELPOK is used as the backbone for these designs, but these sites can be used in many different polymer backbone sequences. The insert location is chosen to permit accessibility of the site to the catalytic groove of the protease. Most proteases will bind up to 4 upstream amino acids from the cleavage site. Therefore, the insert sequences should be free of hydrogen bonding and crystallization that may be induced by, for example, silk-like blocks.

The beta structure of the SELPOK will break after the proline of the first elastin-like block. SELPOK-CS 1 contains two adjacent cleavage sites for collagenase (PLGP) (SEQ ID NO: 17) within a six amino acid insert. The insertion site was chosen to be removed from the silk-like blocks by at least one proline amino acid (GAGAGS GVGVP L G P L G P GVGVP) (SEQ ID NO:18). SELPOK-CS2 contains multiple cleavage sites for cathepsins B (ARR), L (FF), S and H (FVR) and plasmin (R) within an eight amino acid insert. The insertion site was chosen to be removed from the silk-like blocks by at least one proline amino acid (GAGAGS GVGVP G F F V R A R R GVGVP)(SEQ ID NO:19).

Construction of Plasmid pPT0317

Plasmid DNA pSY1262 (see U.S. Pat. No. 5,243,038) was linearized with PvuII REN, then passed through a Probind filter and a Bio-Spin 6 column. The DNA was then treated with Shrimp Alkaline Phosphatase (SAP). The linearized pSY1262 DNA was then ligated with a DNA fragment from pQE-17 (QIAGEN .Catalog #33173) prepared as follows. Plasmid DNA pQE-17 was digested with BglII and HindIII RENs and the 36 by fragment shown in Table 6 was purified using a Probind filter and a Biospin column. The DNA was purified further using a Microcon-30 filter and the filtrate, containing the 36 by fragment, was kept. The DNA was then treated with DNA Polymerase I and purified using a Probind filter and a Biospin column (see Example 1). TABLE 6 5′-GATCTTCGATCTCATCACCATCACCATCACTA (SEQ ID NO:20) 3′-AAGCTAGAGTAGTGGTAGTGGTAGTGATTCG (SEQ ID NO:21)

The product of the ligation reaction was transformed into E. coli strain HB 101. Plasmid DNA from transformants was purified and analyzed by digestion using Bstl 1071 and EcoRV RENs. The clones containing the desired DNA fragment were further digested with Bstl 1071 and BstYI RENs to determine the orientation of the insert. Plasmid DNA from the clones showing the correct restriction pattern was purified and analyzed by DNA sequencing. Plasmid pPT0317 contained the desired DNA insert and was used for further DNA constructions.

SELPOK Polymer Construction

One oligonucleotide strand as shown in Table 7 was synthesized using an Applied Biosystems DNA synthesizer model 381A and a 2000A synthesis column supplied by Glen Research. After the synthesis the 93 base DNA fragment was deprotected and cleaved from the column support by treatment in ammonium hydroxide at 55° C. for 6 hours. TABLE 7 (SEQ ID NO:22) 5′-ATGGCAGCGAAAGGGGACCGGTGCCGGCGCAGGTAGCGGAGCCGGTG CGGGCTCAAAAAGGGCTCTGGTGCCTTTCCGCTAAAGTCCTGCCGT -3′

The PCR reaction was performed using the same two DNA primer strands as described for the construction of the SELP8K gene monomer and the reaction product was purified. The DNA was resuspended and digested with Banl REN. The digested DNA was then separated by low-melting agarose gel and ligated with pPT0285 (see PCT/US92/09485) previously digested with Banl REN and purified by NACS column. The product of the ligation reaction was: transformed into E. coli strain H13101. Plasmid DNA from transformants was purified and analyzed by digestion using EcoRI and BaniI RENs. Plasmid DNA from the clones showing the correct restriction pattern was then purified and analyzed by DNA sequencing. Plasmid pPT0358 contained the desired sequence and was used for subsequent DNA constructions.

Plasmid DNA from pPT0340 was digested with Banll REN and the digestion fragments were separated by agarose gel electrophoresis. The SELPOK gene fragment, 156 bp, (see Table 8), was excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column. TABLE 8 (SEQ ID NOS:23&24) BanII G   GGC TCT GGT GTT GGA GTG CCA GGT GTC GGT GTT CCG GGT GTA GGC GTT C   CCG AGA CCA CAA CCT CAC GGT CCA CAG CCA CAA GGC CCA CAT CCG CAA     G       S       G       V       G       V       P       G       V     G       V       P       G       V       G       V CCG GGA GTT GGT GTA CCT GGA AAA GGT GTT CCG GGG GTA GGT GTG CCG GGC CCT CAA CCA CAT GGA CCT TTT CCA CAA GGC CCC CAT CCA CAC GGC P       G       V       G       V       P       G       K       G       V     P       G       V       G       V       P GGC GTT GGA GTA CCA GGT GTA GGC GTC CCG GGA GCG GGT GCT GGT AGC CCG CAA CCT CAT GGT CCA CAT CCG CAG GGC CCT CGC CCA CGA CCA TCG G       V       G       V       P       G       V       G       V       P     G       A       G       A       G       S BanII GGC GCA GGC GCG GGC TC CCG CGT CCG CGC CCG AG G       A       G       A       G       S

The purified fragment was ligated with plasmid pPT0358 which had been digested with Banll REN, then passed through a Probind filter and a Microcon-30 filter. The digestion fragments were then separated by agarose gel electrophoresis. The plasmid DNA was then excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column (see Example 1).

The product of this ligation reaction was transformed into E. coli strain HB 101. Transformants were selected for resistance to chloramphenicol. Plasmid DNA from individual transformants was purified and analyzed for increased size due to SELPOK multiple DNA insertion. Several clones were obtained with inserts of different sizes. Plasmid pPT0359, pPT0360 and pPT0374 containing respectively 18, 2 and 6 repeats of the SELPOK gene monomer were used for subsequent instructions.

Plasmid DNA from pPT0359 and pPT0374 was digested with BanI REN and the digestion fragments were separated by agarose gel electrophoresis. The SELPOK gene fragments, approximately 2800 by and 1000 bp, were excised and purified by NACS column. The purified fragments were then ligated with plasmid pPT0317 which had been digested with BanI REN, then passed through a Probind filter and Bio-Spin 6 column. The DNA was then treated with Shrimp Alkaline Phosphatase (SAP), passed through a Probind filter and then a Bio-Spin 6 column (see Example 1).

The product of these ligation reactions was transformed into E. coli strain 1113101. Transformants were selected for resistance to kanamycin. Plasmid DNA from individual transformants was purified and analyzed for increased size due to SELPOK multiple DNA insertion. Several clones were obtained. Plasmid pPT0364 and pPT0375 were chosen to be used for expression of SELPOK.

SELPOK Expression Analysis

E. coli strain HB 101 containing plasmid pPT0364 and pPT0375 were grown as described in Example 1. The proteins produced by these cells were analysed by SDS-PAGE for detection of reactivity to ELP antibodies. In every analysis a strong reactive band was observed of an apparent molecular weight of approximately 95 kD and 35 kD respectively. (SEQ ID NO:25) PT0364        SELPOK      1000 AA      MW 80,684 MDPVVLQRRDWENPGVTQLNRLAAHPPFASDPM [(GAGAGS)₂    (GVGVP)₄GKGVP (GVGVP)₃]₁₀ (GAGAGS)₂     GAGAMDPGRYQDLRSHHHHHH (SEQ ID NO:26) pPT0375        SELPOK       376 AA      MW 31,445 MDPVVLQRRDWENPGVTQLNRLAAHPPFASDPM [(GAGAGS)₂    (GVGVP)₄GKGVP (GVGVP)31₆ (GAGAGS)₂     GAGAMDPGRYQDLRSHHHHHH

SELPOK-CS 1 Polymer Construction

Plasmid pPT0360 was digested with Banl REN and the digestion fragments were separated by agarose gel electrophoresis. The SELPOK gene fragment, approximately 300 bp, was excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column. The purified fragment was ligated with plasmid pPT0134 (see PCT/US92/09485) which had been digested with Fold REN. The enzyme was heat inactivated at 65° C. for 20 minutes and the ligation mixture was then passed through a Probind filter. The DNA was then treated with Shrimp Alkaline Phosphatase (SAP), passed through a Probind filter and then a Bio-Spin 6 column.

The product of this ligation reaction was transformed into E. coli strain HB101. Transformants were selected for resistance to chloramphenicol. Plasmid DNA from individual transformants was purified and analyzed by digestion using Dral REN. One plasmid, pPT0363, showed the correct restriction pattern and was used for subsequent DNA constructions.

One oligonucleotide strand as shown in Table 9 was synthesized using an Applied Biosystems DNA synthesizer model 381A and a 2000A synthesis column supplied by Glen Research. After the synthesis the 141 base DNA fragment was deprotected and cleaved from the column support by treatment in ammonium hydroxide at 55° C. for 6 hours. TABLE 9 (SEQ ID NO:27) 5′-ATGGCAGCGAAAGGGGACCGCCGGTGCGGGCTCTGGTGTTGGAGTGC CGCTGGGTCCTCTTGGCCCAGGTGTCGGTGTTCCGGGTGTAGGCGTTCCG GGAGTTGGTGTACCTGGAAAAGGTTTCCGCTAAAGTCCTGCCGT-3′

The PCR reaction was performed using the same two DNA primer strands as described for the construction of the SELP8K gene monomer and the reaction product was purified. The DNA was then resuspended and digested with BsrFI and EcoNI RENs. The digested DNA was treated with Probind and Microcon-30 filters, a Bio-Spin 6 column, and then ligated with pPT0363 previously digested with BsrFI REN, treated with a ProBind filter and a Bio-Spin 6 column and then further digested with EcoNI REN. The digestion fragments were separated by agarose gel electrophoresis. The larger DNA band, approximately 2000 bp, was excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column (see Example 1).

The product of the ligation reaction was transformed into E. coli strain HB 101. Plasmid DNA from individual transformants was purified and analyzed by digestion using Asp7001 and EcoO 1091 RENs. Plasmid DNA from the clones showing the correct restriction pattern was then purified and analyzed by DNA sequencing. Plasmid pPT0368 (see Table 10) contained the desired sequence and was used for subsequent DNA constructions. TABLE 10 (SEQ ID NOS:28 & 29) BanII G   GGC TCT GGT GTT GGA GTG CCG CTG GGT CCT CTT GGC CCA GGT GTC C   CCG AGA CCA CAA CCT CAC GGC GAC CCA GGA GAA CCG GGT CCA CAG     G       S       G       V       G       V       P       L       G     P       L       G       P       G       V GGT GTT CCG GGT GTA GGC GTT CCG GGA GTT GGT GTA CCT GGA AAA CCA CAA GGC CCA CAT CCG CAA GGC CCT CAA CCA CAT GGA CCT TTT G       V       P       G       V       G       V       P       G       V     G       V       P       G       K GGT GTT CCG GGG GTA GGT GTG CCG GGC GTT GGA GTA CCA GGT GTA CCA CAA GGC CCC CAT CCA CAC GGC CCG CAA CCT CAT GGT CCA CAT G       V       P       G       V       G       V       P       G       V     G       V       P       G       V                             BanII GGC GTC CCG GGA GCG GGT GCT GGT AGC GGC GCA GGC GCG GGC TCT CCG CAG GGC CCT CGC CCA CGA CCA TCG CCG CCT CCG CGC CCG AGA G       V       P       G       A       G       A       G       S       G     A       G       A       G       S

Plasmid DNA pPT0368 was digested with BanlI REN, and the digestion fragments were separeted by agarose gel electrophoresis. The SELPOK-CS1 gene fragment, 174 bp, was excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column. The purified fragment was ligated with plasmid pPT0358 which had been digested with BanlI REN, then passed through a Probind filter and a Microcon-30 filter. Subsequently the digestion fragments were separated by agarose gel electrophoresis. The plasmid DNA was then excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column (see Example 1).

The product of this ligation reaction was transformed into E. coli strain HB101. Transformants were selected for resistance to chloramphenicol. Plasmid DNA from individual transformants was purified and analyzed for increased size due to SELPOK-CS 1 multiple DNA insertion. Several clones were obtained with insert sizes ranging from 1000 by to approximately 3000 bp. Plasmid pPT0369 containing 16 repeats of the SELPOK-CS 1 gene monomer was used for subsequent constructions.

Plasmid DNA from pPT0369 was digested with BanI REN, followed by a Probind filter and then the digestion fragments were separated by agarose gel electrophoresis. The SELPOK-CS1 gene fragment, approximately 2800 bp, was excised and purified by an Ultrafree-MC filter and desalted using a Bio-Spin 6 column. The purified fragments were then ligated with plasmid pPT0317 which had been digested with BanI REN and then passed through a Probind filter and a BioSpin 6 column. The DNA was then treated with Shrimp Alkaline Phosphatase (SAP), passed through a Probind filter and then a Bio-Spin 6 column (see Example 1).

The product of these ligation reactions was transformed into E. coli strain HB 101. Transformants were selected for resistance to kanamycin. Plasmid DNA from individual transformants was purified and analyzed for increased size due to SELPOK-CS 1 multiple DNA insertion. Several clones were obtained. Plasmid pPT0370 was chosen to be used for expression of SELPOK-CS 1.

SELPOK-CS1 Expression Analysis

E. coli strain HB 101 containing plasmid pPT0370 was grown as described in Example 1. The proteins produced by these cells were analysed by SDS-PAGE for detection of reactivity to ELP antibodies. In every analysis a strong reactive band was observed with an apparent molecular weight of approximately 90 kD. (SEQ ID NO:30) pPT0370        SELPOK-CS1      934 AA      MW 76,389 MDPVVLQRRDWENPGVTQLNRLAAHPPFASDPM [(GAGAGS)Z  (GVGVP)₁LGPLGP (GVGVP)₃GKGVP(GVGVP)₃]₁₅ (GAGAGS)₂       GAGAMDPGRYQDLRSHHHHHH

SELPOK-CS2 Polymer Construction

One oligonucleotide strand as shown in Table 11 was synthesized using an Applied Biosystems DNA synthesizer model 381A and a 2000A synthesis column supplied by Glen Research. After the synthesis the 147 base DNA fragment was deprotected and cleaved from the column support by treatment in ammonium hydroxide at 55° C. for 6 hours. TABLE 11 (SEQ ID NO:31) 5′-ATGGCAGCGAAAGGGGACCGCCGGTGCGGGCTCTGGTGTTGGAGTGC CAGGCTTCTTTGTACGTGCACGCCGTGGTGTCGGTGTTCCGGGTGTAGGC GTTCCGGGAGTTGGTGTACCTGGAAAAGGTTTCCGCTAAAGTCCTGCCGT -3′

The PCR reaction was performed using the same two DNA primer strands as described for the construction of the SELP8K gene monomer and the reaction product was purified. The DNA was then resuspended and digested with BsrFI and EcoNI RENs. The digested DNA was treated with ProBind and Microcon-30 filters, a Bio-Spin 6 column, and then ligated with pPT0363 previously digested with BsrFI REN, treated with a ProBind filter and a Bio-Spin 6 column and then further digested with EcoNI REN. The digestion fragments were separated by agarose gel electrophoresis. The larger DNA band, approximately 2000 bp, was excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column.

The product of the ligation reaction was transformed into E. coli strain HB101. Plasmid DNA from individual transformants was purified and analyzed by digestion using Asp7001 and DraIII RENs. Plasmid DNA from the clones showing the correct restriction pattern was then purified and analyzed by DNA sequencing. Plasmid pPT0367 (see Table 12) contained the desired sequence and was used for subsequent DNA constructions. TABLE 12 (SEQ ID NOS:32&33) BanII G   GGC TCT GGT GTT GGA GTG CCA GGC TTC TTT GTA CGT GCA CGC CGT C   CCG AGA CCA CAA CCT GAG GGT CCG AAG AAA CAT GCA GGT GCG GCA     G       S       G       V       G       V       P       G       F       F         V       R       A       R       R GGT GTC GGT GTT CCG GGT GTA GGC GTT CCG GGA GTT GGT GTA CCT GGA GCA GAG CCA CAA GGC CCA CAT CGG CAA GGC CTT CAA CCA CAT GGA CCT G       V       G       V       P       G       V       G       V       P     G       V       G       V       P       G AAA GGT GTT CCG GGG GTA GGT GTG CCG GGC GTT GGA GTA CCA GGT GTA TTT CCA CAA GGC CCC CAT CCA GAG GGC CCG CAA CCT CAT GGT CCA CAT K       G       V       P       G       V       G       V       P       G     V       G       V       P       G       V                             BanII GGC GTG CCG GGA GCG GGT GGT GGT AGC GGC GCA GGC GGG GGG TC GCG GAG GGC CCT CGC CCA CGA GGA TCG GCG GGT CCG CGC CCG AG G       V       P       G       A       G       A       G       S       G     A       G       A       G       S

Plasmid DNA pPT0367 was digested with Banll REN, treated with a Probind filter and a Bio-Spin6 column and then the digestion fragments were separated by agarose gel electrophoresis. The SELPOK-CS2 gene fragment, 180 bp, was excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column. The purified fragment was ligated with plasmid pPT0358 which had been digested with Banll REN and then passed through a Probind filter and a Microcon-30 filter. Subsequently the digestion fragments were separated by agarose gel electrophoresis. The plasmid DNA was then excised and purified using an Ultrafree-MC filter followed by Bio-Spin 6 column (see Example 1).

The product of this ligation reaction was transformed into E. coli strain HB 101. Transformants were selected for resistance to chloramphenicol. Plasmid DNA from individual transformants was purified and analyzed for increased size due to SELPOK-CS2 multiple DNA insertion. Several clones were obtained with insert sizes ranging from 200 by to approximately 3000 bp. Plasmid pPT0371 and pPT0372, containing 18 and 15 repeats respectively of the SELPOK-CS2 gene monomer were used for subsequent constructions.

Plasmid DNA from pPT0372 was digested with Banl REN, followed by a Probind filter, and then the digestion fragments were separated by agarose gel electrophoresis. The SELPOK-CS2 gene fragment, approximately 2800 bp, was excised and purified by an Ultrafree-MC filter and desalted using a Bio-Spin 6 column. The purified fragments were then ligated with plasmid pPT0317 which had been digested with Banl REN, passed through a Probind filter and then a Bio-Spin 6 column. The DNA was treated with Shrimp Alkaline Phosphatase (SAP), passed through a Probind filter and then a Bio-Spin 6 column (see Example 1).

The product of these ligation reactions was transformed into E. coli strain HD 101. Transformants were selected for resistance to kanamycin. Plasmid DNA from individual transformants was purified and analyzed for increased size due to SELPOK-CS2 multiple DNA insertion. Several clones were obtained. Plasmid pPT0373 was chosen to be used for the expression of SELPOK-CS2.

SELPOK-CS2 Expression Analysis

E. coli strain HB 101 containing plasmid pPT0373 was grown as described in Example 1. The proteins produced by these cells were analysed by SDS-PAGE for detection of reactivity to ELP antibodies. In every analysis a strong reactive band was observed of an apparent molecular weight of approximately 90 kD. (SEQ ID NO:34) pPT0373        SELPOK-CS2      964 AA       MW 83,218 MDPVVLQRRDWENPGVTQLNRLAAHPPFASDPM [(GAGAGS)₂  (GVGVP)₁ GFFVRARR(GVGVP)₃ GKGVP (GVGVP)₃]₁₅ (GAGAGS)₂  GAGAMDPGRYQDLRSHHHHHH

SELPOK and SELPOK-CS1 Purification

SELPOK and SELPOK-CS 1 were produced in E. coli strains pPT0364 and pPT0370, respectively. The products were purified from the cellular biomass by means of cellular lysis, clearance of insoluble debris by polyethylene imine precipitation and centrifugation, ammonium sulfate precipitation, and anion exchange chromatography. The purified products were analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), immunoreactivity with a polyclonal antisera which reacts with elastin-like peptide blocks (ELP antibody), and amino acid analysis.

For SELPOK, a protein band of apparent molecular weight 95,000 was observed by amido black staining of SDS-PAGE separated and transferred samples and the same band reacted with the ELP antibody on Western blots. As expected, amino acid analysis (shown in Table 13) indicated that the product was enriched for the amino acids glycine (41.0%), alanine (8.0%), serine (4.5%), proline (14.1%), and valine (26.8%). The product also contained 1.9% lysine. The amino acid composition table below shows the correlation between the composition of the purified product and the expected theoretical composition as deduced from the synthetic gene sequence. TABLE 13 Amino Acid Analysis of Purified SELPOK pMoles Mole % Theoretical Mole ASX 28.10 0.6 0.7 GLX 26.90 0.6 0.4 SER 199.84 4.5 4.0 GLY 1812.07 41.0 40.5 HIS 28.45 0.6 0.7 ARG 20.49 0.5 0.5 THR 0 0.0 0.1 ALA 355.29 8.0 8.0 PRO 623.22 14.1 15.0 TYR 8.47 0.2 0.1 VAL 1183.63 26.8 27.3 MET 17.21 0.4 0.3 ILE 4.83 0.1 0.0 LEU 20.66 0.5 0.4 PHE 7.57 0.2 0.1 LYS 84.02 1.9 1.8 Total 4420.75

For SELPOK-CS1, a protein band of apparent molecular weight 90,000 was observed by amido black staining of SDS-PAGE separated and transferred samples and the same band reacted with the ELP antibody on Western blots. As expected, amino acid analysis (shown in Table 14) indicated that the product was enriched for the amino acids glycine (40.0%), alanine (7.6%), serine (5.2%), proline (16.3%), and valine (23.3%). The product also contained 1.5% lysine. The amino acid composition table below shows the correlation between the composition of the purified product and the expected theoretical composition as deduced from the synthetic gene sequence. TABLE 14 Amino Acid Analysis of Purified SELPOK-CS1 pMoles Mole % Theoretical Mole ASX 16.43 0.7 0.7 GLX 10.59 0.5 0.4 SER 119.96 5.2 3.6 GLY 924.51 40 0 39.6 HIS 13.85 0.6 0.7 ARG 11.26 0.5 0.5 THR 0 0.0 0.1 ALA 175.07 7.6 7.3 PRO 376.40 16.3 16.7 TYR 2.49 0.1 0.1 VAL 537.96 23.3 24.5 MET 5.19 0.2 0.3 ILE 0 0.0 0.0 LEU 76.62 3.3 0.4 PHE 2.58 0.1 0.1 LYS 35.68 1.5 1.6 Total 2308.59

Example 4 Evaluation of CLP6 and SELP8K Properties

Test Procedures

Tiseel Adhesive Systems. Rat skins were washed with water, blotted dry and cut into strips about 1 cm×4 cm. Adhesive from Tiseel Kit VH (Osterreiches Institute Fur Haemoderivate, GmbH, A-1220, Vienna, Austria) was applied according to the manufacturer's specifications.

Rat Skin Lap Shear Tensile Strength Assay. Adhesive formulations were tested for their ability to bond skin together using an in vitro rat skin lap shear tensile strength assay. Adhesives were applied to the subcutaneous side of a strip of harvested rat skin. A second skin strip was overlapped in order to produce an approximate bonding surface of 1 cm2. A 100 gram weight was applied to the lap joint and the adhesive was allowed to cure, usually at room temperature for a period of 2 hours and wrapped in plastic to prevent desiccation. The lap joint was mounted on an Instron Tensile Tester or similar apparatus and tensile force applied. With the Instron, tensile force was typically applied at a constant strain rate of 2 inches per minute. The load at failure was recorded and normalized to the measured area of overlap.

Adhesive Systems with Glutaraldehyde. Rat skins were washed with water, blotted dry, and cut into strips about 1 cm×4 cm. Glutaraldehyde was distilled, stored frozen and thawed immediately before use. Bovine serum albumin was dissolved according to Goldman's specifications (Goldman, W094/01508). CLP6 was dissolved at 600 mg/mL in 150 mM HEPES+30 mM NaCl and adjusted to pH 7.5. SELP8K was dissolved at the concentrations indicated in Table 15 in 150 mM HEPES+45 mM NaCl and adjusted to pH 8. The indicated aliquots of the solution of protein was spread over both skins before the addition of the glutaraldehyde solution. The second skin was overlaid, rubbed across the lower skin to distribute the components, adjusted to an overlap area of ca. 1 cm2, covered with plastic wrap to prevent drying, and cured for 2 hours at 25° C. under a compressive force of 100 g/cmZ.

Adhesive S stems with 1 6-(Diisocyanto)hexane. Rat skins were washed with water, blotted dry, and cut into strips about 1 cm×4 cm. A solution of SELP8K was made up in the specified buffer at a concentration of ca. 50% w/w. A 1:1 v/v mixture of hexamethylene diisocyanate (HMDI) and Pluronic L-61 surfactant was prepared. A 20 μL aliquot of SELP8K solution was applied to one skin followed by a 2 μL aliquot of the diluted HMDI. The second skin was overlaid, rubbed across the lower skin to mix the components, adjusted to ca. 1 cm² overlap, covered with plastic wrap to prevent drying, and cured for 2 hours at 25° C. under a compressive force of 100 g/cm².

Results

In order to provide a baseline for subsequent adhesive experiments, ethyl cyanoacrylate and Tiseel fibrin glue were evaluated. These results are reported in the following table. TABLE 15 Base Case Lap Shear Tensile Strengths Tensile Strength Reagent Dose g/cm² Normal Saline not applicable 13 ± 4 Tiseel Fibrin Glue ˜25 mg   261 ± 51 Ethyl cyanoacrylate 25 mg  385 ± 119

All data reported are based on at least three test specimens. All test results are based on a two hour cure time.

The subject compositions were compared to the proteinaceous adhesive system described by Goldman (W094/01508). Ten microliters of glutaraldehyde solution of the indicated concentration was added in all cases. The following table indicates the results. TABLE 16 Lap Shear Tensile Strength of Glutaraldehyde Cured Adhesive Systems Tensile Strength Reagent Dose g/cm² Ovalbumin + Glutaraldehyde  6 mg/2.5 mg 50 ± 10 (30μ) 200 mg/mL 10 μL 2.5N Atelocollagen(denat) + Glutaraldehyde  3 mg/2.5 mg 148 ± 47  (25 μL) 125 mg/mL 10 μL 2.5N CLP6 + Glutaraldehyde 24 mg/2.5 mg 306 ± 98  (40 μL) 600 mg/mL 10 μL 2.5N CLP6 + Glutaraldehyde 12 mg/2.5 mg 171 ± 42  (20 μL) 600 mg/mL 10 μL 2.5N SELP8K (30 μL) + Glutaraldehyde 600 mg/mL 1.0N 18 mg/1 mg 545 ± 153 300 mg/mL 1.0N  9 mg/1 mg 452 ± 54  300 mg/mL(impure) 1.0N  9 mg/1 mg 234 ± 51* 300 mg/mL(impure) 0.1N  9 mg/0.1 mg 210 ± 57* 287 mg/mL 2.5N  7 mg/2.5 mg 374 ± 90  100 mg/mL 1.0N  3 mg/1 mg 361 ± 47  100 mg/mL 2.5N  3 mg 12.5 mg 274 ± 17  *This preparation of SELP8K was known to be impure and is estimated to yield adhesive strength about one-half of that of the more completely purified material.

This preparation of SELP8K was known to be impure and is estimated to yield adhesive strength about one-half of that of the more completely purified material.

The data in the above table demonstrate that the subject polymers are able to provide superior adhesive capabilities when used in the glutaraldehyde cured system under conditions comparable to collagen and ovalbumin. Despite the lower number of amino groups available for crosslinking, the SELP8K polymer provides the highest tensile strengths in the rat skin lap shear results. The above results demonstrate that significant adhesion can be obtained at even low doses of glutaraldehyde down to 100 μg/cm2. The quality and purity of the glutaraldehyde is known to be critical to obtain good crosslinking (Rujigrok, DeWijn, Boon, J. Matr. Sci. Matr. Med. 5:80-87 (1994); Whipple, Ruta, J. Org. Chem. 39:1666-1668 (1974). The glutaraldehyde used in these experiments was distilled, diluted to 2.5N and stored at −20° C. until used.

In the next study, hexamethylene diisocyanate was employed. It was found necessary to add an equal volume of diluent to obtain good adhesion, since the curing was otherwise too fast. The following table indicates the results, where n=12. TABLE 17 Lap Shear Tensile Strength of HMDI Derived Adhesive System Tensile Reagent Dose Strength g/cm2 SELP8K 20 μL × 50% w/w 10 mg  585 ± 203 HMDI/L-61 1:1 v/v 2 μL × 50% v/v  1 mg Buffer: (100 μL water + 10 μL 1M KHCO₃) SELP8K 20 μL × 50% w/w 10 mg 503 ± 21 HMDI/L-61 1:1 v/v 2 μL × 50% v/v  1 mg Buffer: (100 μL 50 mM PO, (pH 6.8) + 5 μL 1M KHCO₃) SELP8K 20 μL × 50% w/w 10 mg 451 ± 67 HMDI/L-61 1:1 v/v 2 μL × 50% v/v  1 mg Buffer: (100 μL 50 mM PO₄ (pH 6.8) + 10 μL 1M KHCO₃) SELP8K 20 μL × 50% w/w 10 mg 362 ± 71 HMDI/L-61 1:1 v/v 2 μL × 50% v/v  1 mg Buffer: (100 μL 50 mM P0₄ (pH 6.8))

Example 5 Evaluation of SELPOK (SEOK) and SELPOK-CS 1 Properties

A number of formulations were prepared using different components for the formulation and determining the lap shear strength. In addition a variety of protocols were used to prepare the protein dope to provide adhesion. These protocols are set forth as follows: Protocol A. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 13.1:1  

Preparation of Protein Dope

The designation 1:2 refers to the nominal ratio of amino groups derived from lysine to amino groups derived from SEOK. The designation 1:1 refers to the nominal ratio of carbonate ions per amino group from SEOK plus lysine. The designation 13.1:1 refers to the nominal ratio of isocyanate groups to amine groups from SEOK plus lysine

A stock buffer solution was prepared by dissolving lysine hydrochloride 0.0157 g, potassium carbonate 0.0710 g, and Evans Blue dye 0.00371 g in 7.526 mL of deionized water. Stock buffer, 620.6 μL, was added to SEOK, 127.1 mg in an Eppendorf tube. The mixture was agitated on a vortex mixer until complete dissolution occurred. The solution was centrifuged at about 5000 rpm for 30-60 seconds to separate air bubbles. The solution was then loaded into a 1 mL syringe for dispensing onto the test skins. The optional inclusion of dye in the protein dope serves to more readily visualize the distribution of the dope on the test skins.

Preparation of HMDI Setting Agent

The HMDI setting agent was prepared by dissolving Sudan Red dye, 1.75 mg, in neat 1,6-diisocyanatohexane, 1.00 g. The optional inclusion of dye in the setting agent serves to more readily visualize the distribution of the setting agent on the test skins.

Preparation of Rat Skins

Freshly harvested rat hides were stored frozen at −20° C. Just before use the hides were thawed and cut into 1 cm×3 cm strips. All fascia was removed from the strips of skin with a razor blade. Strips of skin were selected which were uniform in width and thickness. Prepared rat skin samples were temporarily stored at 37° C. between gauze pads soaked with PBS and contained in a plastic bag to prevent drying.

Application of Adhesive

In a 37° C. warm room, protein dope, 15 μL, was applied to each of two strips of rat skin, 30 μL total, and aggressively worked into about a 1 cm² area of each piece of skin with a stainless steel spatula. A total of 1.8 μL of HMDI setting agent was applied to the skins, apportioned so that 3 parallel stripes of HMDI were applied to the first skin and two stripes in an X-pattern were applied to the second skin. The skins were immediately assembled to form the lap joint, covered with a piece of plastic film to prevent drying, and compressed under a 100 g weight. The joint was allowed to cure for 15 minutes at 37° C. The length and width of the lap joint was measured to 1 mm using a ruler immediately before tensile testing on an Instron Model 55 test machine. The crosshead speed was set at 25 mm per minute. Lap shear tensile strengths were reported in units of g/cm². Means and standard deviations were calculated for measurements conducted at least in triplicate. Protocol B. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 14.5:1  

The steps of Protocol A were followed, except that bubbles were removed from the protein dope in a two stage process. After centrifugation, the dope was exposed to reduced pressure, 26 in-Hg, for 30 minutes. The volume of HMDI setting agent applied to the lap joint was 2.0 μL. Protocol C. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 7.3:1  

The steps of Protocol B were followed, except that the composition of the HMDI setting agent was altered. Sudan Red dye, 5.2 mg was dissolved in 10.735 g of neat Pluronic surfactant L-31 by beating to 100° C. for 10 minutes. After cooling to room temperature, an equal weight of 1,6-diisocyanatohexane was added to this mixture. The mixture was prepared immediately before use. Protocol D1 SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that Pluronic surfactant L-3 1, 4.57 mg, was added to SEOK, 74.6 mg. The ratio of SEOK to lysine buffer solution remained as described in Protocol B. Protocol D2 SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that Pluronic surfactant L-3 1, 1.07 mg, was added to SEOK, 74.7 mg. The ratio of SEOK to lysine buffer solution remained as described in Protocol B. Protocol E. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 7.3:1  

The steps of Protocol B were followed, except that in Protocol E, 5.1 mg Pluronic L-31 was added to 85.0 mg SEOK. The composition of the HMDI setting agent was also altered. Sudan Red dye, 5.2 mg was dissolved in 10.735 g neat Pluronic surfactant L-31 by heating to 100° C. for 10 minutes. After cooling to room temperature, an equal weight of 1,6-diisocyanatohexane was added to this mixture. The mixture was prepared immediately before use. Protocol F. SEOK 17% w/w Lysine hydrochloride 1:2 Sodium Borate pH 9.5 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that a stock buffer solution was prepared by dissolving lysine hydrochloride 0.46 g, boric acid 1.24 g in 92.2 mL of deionized water. The pH of this solution was adjusted to pH 9.52 by the addition of 7.8 ml, of 2 N sodium hydroxide solution. Evans Blue dye, 0.50 mg/mL, was dissolved in this buffer, and the solution filtered through a 0.45 micron syringe filter. Stock buffer, 333.5 μL, was added to SEOK, 68.3 mg in an Eppendorf tube. The mixture was agitated on a vortex mixer until complete dissolution occurred. Protocol G. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Borate pH 9.5 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that a stock buffer solution was prepared by dissolving lysine hydrochloride, 0.46 g, and boric acid, 1.24 g in 99.1 mL of deionized water. The pH of this solution was adjusted to pH 9.52 by the addition of 0.9 ml, of 10 N potassium hydroxide solution. Evans Blue dye, 0.50 mg/mL, was dissolved in this buffer, and the solution filtered through a 0.45 micron syringe filter. Stock buffer, 367.2 μL, was added to SEOK, 75.2 mg in an Eppendorf tube. The mixture was agitated on a vortex mixer until complete dissolution occurred. Protocol H. SEOK 17% w/w Lysine hydrochloride 1:2 Lithium Carbonate pH 9.5 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that the stock buffer solution was prepared by dissolving lysine hydrochloride, 42.7 mg, in deionized water, 10.0 mL, and adding lithium carbonate, 14.3 mg, to pH 9.55. Evans Blue dye, 0.50 mg/mL, was dissolved in this buffer, and the solution filtered through a 0.45 micron syringe filter Protocol I. SEOK 17% w/w Lysine hydrochloride 1:2 Sodium Carbonate pH 9.5 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that the stock buffer solution was prepared by dissolving sodium carbonate, 1.06 g, and lysine hydrochloride, 0.46 g, in 99.2 ml, of deionized water. Using concentrated hydrochloric acid solution 0.8 mL, the solution was adjusted to pH 9.54. Evans Blue dye, 0.50 mg/mL, was dissolved in this buffer, and the solution filtered through a 0.45 micron syringe filter Protocol J. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate pH 9.5 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that the stock buffer solution was prepared by dissolving potassium carbonate, 1.38 g, and lysine hydrochloride, 0.46 g, in 99.1 mL of deionized water. Using concentrated hydrochloric acid solution, 0.9 mL, the solution was adjusted to pH 9.53. Evans Blue dye, 0.50 mg/mL, was dissolved in this buffer, and the solution filtered through a 0.45 micron syringe filter. Protocol K. SEOK 17% w/w Lysine hydrochloride 1:2 Cesium Carbonate pH 9.5 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that the stock buffer solution was prepared by dissolving lysine hydrochloride, 42.7 mg, in deionized water, 10.0 mL, and adding cesium carbonate, 55.2 mg, to pH 9.52. Evans Blue dye, 0.50 mg/mL, was dissolved in this buffer, and the solution filtered through a 0.45 micron syringe filter Protocol L. SEOK 17% w/w Lysine hydrochloride 1:2 Calcium Carbonate 1:1 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that the stock buffer solution was prepared by dissolving lysine hydrochloride, 20.8 mg, in deionized water, 10.0 mL, and adding calcium carbonate, 68.6 mg. Evans Blue dye, 0.50 mg/mL, was dissolved in this buffer, and the solution filtered through a 0.45 micron syringe filter. Protocol M. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate pH 9.0 Isocyanate:Amine 14.5:1  

The steps of Protocol B were followed, except that the stock buffer solution was prepared by dissolving lysine hydrochloride, 103.9 mg, in deionized water, 50.0 mL, and adding potassium carbonate, 473.3 mg. Using concentrated hydrochloric acid, this buffer was adjusted to pH 9.00. Protocol N1. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate 1:1 Isocyanate:Amine 14.5:1   Iodide:Carbonate 1:2

The steps of Protocol B were followed, except that potassium iodide, 5.70 mg/mL was added to the stock buffer solution. The nominal pH of this dope was about pH 11. Protocol N2. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate pH 9.0 Isocyanate:Amine 14.5:1   Iodide:Carbonate 1:2

The steps of Protocol B were followed, except that potassium iodide, 5.70 mg/mL was added to the stock buffer solution. Using concentrated hydrochloric acid, this buffer was adjusted to pH 9.00. Protocol 01. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate 1:1 Isocyanate:Amine 14.5:1   Glucose 1.09 M

The steps of Protocol B were followed, except that glucose, 1.2755 g, was added to the stock buffer solution, 6.495 mL. This solution was pH 10.5. Protocol 02. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate pH 9.0 Isocyanate:Amine 14.5:1   Glucose 1.09 M

The steps of Protocol B were followed, except that glucose, 1.2755 g, was added to the stock buffer solution, 6.495 mL. Using concentrated hydrochloric acid, this buffer was adjusted to pH 9.00. Protocol P1. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate 1:1 Isocyanate:Amine 14.5:1   Urea 1.5 M

The steps of Protocol B were followed, except that urea, 0.5226 g, was added to the stock buffer solution, 5.807 mL, nominally 1.5 M. This solution was pH 11. Protocol P2. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium Carbonate pH 9.00 Isocyanate:Amine 14.5:1   Urea 1.5 M

The steps of Protocol B were followed, except that urea, 0.5226 g, was added to the stock buffer solution, 5.807 mL. Using concentrated hydrochloric acid, this buffer was adjusted to pH 9.00. Protocol Q. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 7.3

The steps of Protocol B were followed, except that the volume of the HMDI setting agent was reduced to 1.0 μL. Protocol R. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 6.7; 6.5; 6.1:1

The steps of Protocol B were followed, except that the HMDI setting agent was diluted 1:1 w/w, 1:3 w/w, or 1:5 w/w with toluene. The volume of diluted HMDI setting agent applied to the lap joint was 2 μL, 4 μL, or 6 μL, respectively. Protocol S. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 6.1; 5.7; 5.6:1

The steps of Protocol B were followed, except that the HMDI setting agent was diluted 1:1 w/w, 1:3 w/w, or 1:5 w/w with methylcyclohexane. The volume of diluted HMDI setting agent applied to the lap joint was 2 μL, 4 μL, or 6 μL, respectively. Protocol T. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 8.5; 9.4; 9.7:1

The steps of Protocol B were followed, except that the HMDI setting agent was diluted 1:1 w/w, 1:3 w/w, or 1:5 w/w with chloroform. The volume of diluted HMDI setting agent applied to the lap joint was 2 μL, 4 μL, or 6 μL, respectively. Protocol U. SEOK 17% w/w Lysine hydrochloride 1:2 Potassium carbonate 1:1 Isocyanate:Amine 8.0; 8.7; 7.8:1

The steps of Protocol B were followed, except that the HMDI setting agent was diluted 1:1 w/w, 1:3 w/w, or 1:5 w/w with methylene chloride. The volume of diluted HMDI setting agent applied to the lap joint was 2 μL, 4 μL, or 6 μL, respectively. Protocol V1. SEEK 33% w/w Lysine hydrochloride 1:1 Potassium carbonate 3:2 Isocyanate:Amine 5.0:1  

Preparation of Protein Dope

A stock solution of buffer was prepared by dissolving lysine hydrochloride, 9.14 mg/mL, potassium carbonate 41.6 mg/mL, and Evans Blue dye, 0.50 mg/mL deionized water. The mixture was filtered through a glass wool plug before use. SEEK, 113.9 mg, and 227.8 mg of stock buffer were placed in a Eppendorf vial and agitated on a vortex mixer until dissolved. Bubbles were removed from this solution by centrifugation at 5000 rpm for 30 seconds. This protein dope solution was then loaded into a 1.00 mL syringe and let stand for 20 minutes at room temperature before dispensing to the lap joint test specimens.

Preparation of HMDI Setting Agent

The HMDI setting agent was prepared by dissolving Sudan Red dye, 3.75 mg, in Pluronic surfactant L-61, and adding an equal weight of 1,6-diisocyanatohexane.

Preparation of Rat Skins

Freshly harvested rat hides were stored frozen at −20° C. Just before use the hides were thawed and cut into 1 cm×3 cm strips. Strips were. selected which were uniform in width and thickness and which were devoid of loose fascia and muscle tissue. These rat skin samples were temporarily stored at 37° C. between gauze pads soaked with PBS and contained in a plastic bag to prevent drying prior to use.

Application of Adhesive

Protein dope, 35 μL, was applied to one end of a rat skin and worked into about a 1 cm2 area with 5-10 strokes of a stainless steel spatula. The excess protein dope was transferred with the stainless steel spatula to the second strip of rat skin and worked in similarily. A total of 3.8 μL of HMDI setting agent was applied to the skins, apportioned so that 3 parallel stripes of HMDI were applied to the first skin. The skins were immediately assembled to form the lap joint, rubbed against each other to distribute the HMDI setting agent, covered with a piece of plastic film to prevent drying, and compressed under a 100 g weight. The joint was allowed to cure for 15 minutes at 37° C. The length and width of the lap joint was measured to 1 mm using a ruler immediately before tensile testing on an Instron Model 55 test machine. The crosshead speed was set at 25 mm per minute. Lap shear tensile strengths were reported in units of g/cm2. Means and standard deviations were calculated for measurements conducted at least in triplicate. Protocol V2. SEW 33% w/w Lysine hydrochloride 1:2 Potassium carbonate 3:2 Isocyanate:Amine 5.0:1  

The method of Protocol V I was followed except that a stock solution of buffer was prepared by dissolving lysine hydrochloride, 4.59 mg/mL, potassium carbonate 31.2 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. Protocol V3. SEW 33% w/w Lysine hydrochloride 0:2 Potassium carbonate 3:2 Isocyanate:Amine 5.0:1  

The method of Protocol V 1 was followed except that a stock solution of buffer was prepared by dissolving potassium carbonate 13.83 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. Protocol W1. SEOK 17% w/w Arginine   1:4 Potassium carbonate  1.2:1 Isocyanate:Amine 13.1:1

The method of Protocol A was followed except that the buffer was prepared using arginine, 2.4 mg/mL, potassium carbonate, 9.46 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. The volume of HMDI setting agent applied to the lap joint was 2.0 μL. Only the alpha amino group of the arginine is assume to participate in the stoichoimetry of the setting reaction. Protocol W2. SEOK 17% w/w Cysteine 1:2 Potassium carbonate 1:1 Isocyanate:Amine 13.1:1  

The method of Protocol A was followed except that the buffer was prepared using cysteine, 1.38 mg/mL, and potassium carbonate, 9.46 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. The volume of HMDI setting agent applied to the lap joint was 2.0 μL. Protocol W3. SEOK 17% w/w Tyrosine 1:2 Potassium carbonate 1:1 Isocyanate:Amine 13.1:1  

The method of Protocol A was followed except that the buffer was prepared using tyrosine, 2.07 mg/mL, and potassium carbonate, 9.46 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. The volume of HMDI setting agent applied to the lap joint was 2.0 μL. Protocol W4. SEOK 17% w/w 1,3-BDSA 1:2 Potassium carbonate 1:1 Isocyanate:Amine 13.1:1  

The method of Protocol A was followed except that the buffer was prepared using 1,3-benzene disulfonic acid disodium salt monohydrate (1,3-BDSA), 3.79 mg/mL, and potassium carbonate, 9.46 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. The volume of HMDI setting agent applied to the lap joint was 2.0 μL. Protocol X SEOK 17% w/w Peptide   1:2 (SEQ ID NO: 35) RGRGRGKGKGK Potassium carbonate   1:1 Isocyanate:Amine 14.5:1

The method of Protocol A was followed except that the buffer was prepared using synthetic peptide RGRGRGKGKGK (SEQ ID NO:35), 4.4 mg/mL, potassium carbonate, 9.46 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. The volume of HMDI setting agent applied to the lap joint was 2.0 μL. Protocol Y. SEOK 17% w/w Cholinyl lysinate   1:4 Potassium carbonate 1.12:1 Isocyanate:Amine 14.5:1

The method of Protocol B was followed except that the buffer was prepared by dissolving cholinyl lysinate, 29.2 mg, potassium carbonate, 123.9 mg, and Evans Blue dye, 6.0 mg, in deionized water, 13.09 mL. The buffer solution was filtered through a 0.45 micron syringe filter before use. The protein dope was prepared by dissolving SEOK, 63.5 mg, in 310.0 μL of buffer. Protocol Z. SEOK 17% w/w AEGIy 1:4 Potassium carbonate 1:1 Isocyanate:Amine 14.5:1  

The method of Protocol B was followed except that the buffer was prepared using 2-aminoethyl glycinate, AEGIy (see Example 1, diamine synthesis). An aliquot, 28.9 mg, of 2-aminoethyl glycinate in water, 236 mg/mL, and potassium carbonate, 48.6 mg, was dissolved in water, 5.127 mL. Evans Blue dye, 2.20 mg was added, and the solution filtered through a 0.45 micron syringe filter. Protocol AA. SEEK 17% w/w Lysine hydrochloride 1:1 Potassium carbonate 1:1 Isocyanate:Amine 12.0:1  

The method of Protocol V 1 was followed except that the buffer was prepared using lysine hydrochloride, 3.73 mg/mL, potassium carbonate, 11.33 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. Pluronic surfactant L-61 was not added to the HMDI setting agent. The protein polymer used was SE8K. The volume of setting agent applied to the joint was 2.0 μL. Protocol AB. SEOK-CS 1 17% w/w Lysine hydrochloride 0.94:2 Potassium carbonate 0.96:1 Isocyanate:Amine 16.4:1

The method of Protocol A was followed except that the buffer was prepared using lysine hydrochloride, 1.84 mg/mL, potassium carbonate, 8.37 mg/mL, and Evans Blue dye, 0.50 mg/mL in deionized water. The protein polymer used was SEOK-CS1. The volume of setting agent applied to the joint was 2.0 μL. Protocol AC. SEOK 17% w/w Lysine hydrochloride   1:2 Sodium Borate pH 9.5 Isocyanate:Amine 7.3:1

The steps of Protocol F were followed, except that the volume of HMDI setting agent applied to the lap joint was 1.0 μL. Protocol AD. SEOK 17% w/w Lysine hydrochloride   1:2 Sodium Borate pH 9.5 Isocyanate:Amine 7.3:1

The steps of Protocol F were followed, except that the HMDI setting agent was diluted 1:1 v/v, 1:3 v/v, or 1:5 v/v using cyclohexane. The volume of diluted HMDI setting agent applied to the lap joint was 2 μL, 4 μL, or 6 μL, respectively. Protocol AE. SEOK 17% w/w Lysine hydrochloride   1:2 Sodium Borate pH 9.5 Isocyanate:Amine 7.3:1

The steps of Protocol F were followed, except that the HMDI setting agent was diluted *1:1 v/v, 1:3 v/v, or 1:5 v/v using 1,1,1-trichloroethane. The volume of diluted HMDI setting agent applied to the lap joint was 2 gL, 4 gL, or 6 AL, respectively. Protocol AF. SEOK 17% w/w Lysine hydrochloride   1:2 Sodium Borate pH 9.5 Isocyanate:Amine 7.3:1

The steps of Protocol F were followed, except that the HMDI setting agent was diluted 1:1 v/v, 1:3 v/v, 1:5 v/v, or 1:9 v/v using ethyl acetate. The volume of diluted HMDI setting agent applied to the lap joint was 2 gL, 4 gL, 6 ItL, or 10/.LL, respectively. Protocol AG. SEOK-CS1 17% w/w 1,3-PG  0.39:2 Potassium carbonate 0.496:1 Potassium bicarbonate 0.496:1 Isocyanate:Amine  2.5:1

The methods of Protocol B were followed with the following modifications.

Preparation of Protein Dope

Protein polymer SEOK-CS 1, 81.6 mg, was added to 311 AL of deionized water in an Eppendorf tube and agitated on a vortex mixter until dissolved. To this solution was added 11.43 gL of a solution of 1,3-propanediyldiglycinate (1,3-PG) in water, 10% w/w; 14.73 μL of a solution of potassium carbonate in water, 10% w/w; and 9.43 μL of a solution of potassium bicarbonate in water, 10% w/w. The contents were again agitated on the vortex mixer until homogeneous. The solution was centrifuged at about 5000 rpm for 30-60 seconds to separate air bubbles, and i then the dope was exposed to reduced pressure, 26 in-Hg, for 30 minutes.

Preparation of HMDI Setting Agent

Neat 1,6-diisocyanatohexane, 100 mg, and Sudan Red dye, 2.4 mg, were dissolved in 1-chloro-2,2,2-trifluoroethyl diflurormethyl ether, 2.342 g. The volume i of diluted HMDI setting agent applied to the lap joint was 4 μL. Protocol AH. SEOK 17% w/w Lysine 0:1 Potassium carbonate 1:1 Isocyanate:Amine −5.0:1    

Preparation of Protein Dope

Protein dope was prepared by dissolving protein polymer SEOK at 17% w/w in 10 mMolar aqueous lactic acid, 0.90 mg/mL. This protein dope tested approximately pH 3.5 with wide range pH test paper. A solution to initiate curing was prepared by dissolving potassium carbonate, 1.66 g, in deionized water, 10 mL.

Preparation of HMDI Setting Agent

An HMDI setting agent was prepared by dissolving 1,6-diisocyanatohexane, 5.04 g, Pluronic surfactant F-127, 0.0033 g, and Sudan Red dye, 0.0020 g in chloroform, 2.24 g.

Preparation of Rat Skins

Freshly harvested rat hides were stored frozen at −20° C. Just before use the hides were thawed and cut into 1 cm×3 cm strips. All fascia was removed from the strips of skin with a razor blade. Strips of skin were selected which were uniform in width and thickness. Prepared rat skin samples were temporarily stored at 37° C. between gauze pads soaked with PBS and contained in a plastic bag to prevent drying.

Application of Adhesive

The strips of skins were arranged on a glass plate in a 37° C. warm room. Protein dope, 15 AL, was worked into an approximately 1 cm2 area at the end of each of two rat skins using a stainless steel spatula, 30 μL total. The HMDI setting agent, 1.0 AL, was worked into an approximately 1 cm2 area at the end of each of two rat skins using a stainless steel spatula, 2.0 μL total. The potassium carbonate curing solution, 2.0 μL, was added as 6 drops, 3 drops applied to each of the two rat skins and the skins immediately assembled to form a lap joint. A 100 g weight was applied to the joint and the adhesive allowed to cure for 15 minutes at 37° C. The lap joint was tested to failure on an Instron tensile testing machine as described herein.

The first study employed the surfactant Pluronic L-3 1. TABLE 18 Role of Pluronic L-31 Surfactant. Lap L- HMDI + Shear SEOK Dope K₂C0₃ Lys Pluronic g/cm₂ Protocol 1 SEOK 17% 1:1 1:2 none 2143 ± 328 A w/w 2 SEOK 17% 1:1 1:2 none 2901 ± 685 B w/w (degassed) 3 SEOK 17% 1:1 1:2 HMDI/ 1248 ± 370 C w/w (degassed) L-31 1:1 (3.3% w/w Wrt total dope) 4 SEOK 17% 1:1 1:2 none  745 ± 209 D1 w/w (degassed) 5 SEOK 17% 1:1 1:2 none 1499 ± 159 D2 w/w (degassed) + L-31 (0.24% w/w wrt total dope) (1.4% w/w wrt SEOK) 6 SEOK 17% 1:1 1:2 HMDI/  677 ± 284 E w/w L-31 (degassed) + 1:1 L-31 (0.17% (3.3% w/w wrt total w/w dope) (1.0% wrt w/w wrt total SEOK) dope)

In the next sudy, various buffers were employed in conjunction with lysine as the polyfunctional group. TABLE 19 Adhesive Performance Using 17% SELPOK (SEOK) in Various Buffers at pH 9.5. Lap Shear Buffer g/cm² CV % Protocol 1 Na3BO₃/L-Lys (1:2)* 2360 ± 475 20% F 2 K3B0₃/L-Lys (1:2) 2037 ± 338 17% G 3 Li2CO₃/L-Lys (1:2) 188 ± 38 20% H 4 Na₂CO₃/L-Lys (1:2) 1168 ± 274 23% I 5 K2C0₃/L-Lys (1:2) 2393 ± 631 26% J 6 Cs₂CO₃/L-Lys (1:2) 233 ± 56 24% K 7 CaCO₃/L-Lys (1:2) 88 ± 2  2% L *The mole ratio of amino groups derived from lysine to amino groups derived from SELPOK

In the next study various chemically unreactive and reactive additives were added to the formulation to determine the effect of the additives on shear strength. TABLE 20 Adhesive Performance Using 17% SELPOK in Carbonate Buffers with Additives Lap Shear Buffer pH g/cm² CV % Protocol 1 K₂C0₃ (2:2)/L-Lys (1:2) 10.5 9.0 2901 ± 685 24% B M no additive 1617 ± 293 18% 2 K₂C03 (2:2)/L-Lys (1:2) 11 9.0 2538 ± 441 17% N1 N2 plus KI (0.043 Mole/L)  826 ± 211 26% 3 K2C03 (2:2)/L-Lys 10.5 9.0 1896 ± 557 29% 01 02 (1:2) 1398 ± 358 26% plus Glucose (1.09 Mole/L) 4 K₂C03 (2:2)/L-Lys (1:2) 11 9.0 2674 ± 846 32% PI P2 plus Urea (1.50 Mole/L) 239 ± 38 16%

In the next study various organic solvents were employed, where the crosslinking agent was dissolved in the solvent prior to mixing with the aqueous buffered protein solution. TABLE 21 Adhesive Performance Using HMDI Plus Volatile Diluents with 17% SELPOK in Lysine-Borate Buffer pH 9.5. Dilution Setting Ratio Agent Lap Shear CV Diluent bp [v/v] Volume g/cm² % Protocol 1 None n.a. 1:0 1 μL 852 ± 173 20% AC 2 Cyclohexane 81° 1:1 2 μL 900 n.a. AD 1:3 4 μL 953 1:5 6 μL 1053 3 1,1,1- 75° 1:1 2 μL 781 ± 13   2% AE Trichloro 1:3 4 μL 943 ± 119 13% ethane- 1:5 6 μL 816 ± 51   6% 4 Ethyl 77° 1:1 2 μL 869 ± 41  40% AF Acetate 1:3 4 μL 741 ± 296 21% 1:5 1:9 6 μL 685 ± 147 20% 10 μL 658 ± 131

TABLE 22 Adhesive Performance Using HMDI Plus Volatile Diluents with 17% SELPOK in Lysine-Carbonate Buffer pH 10. Setting Ratio agent Lap Shear CV Diluent by [w/w] Volume g/cm² % Protocol 1 None n.a. 1:0 1 μL 2713 ± 234  6% Q 2 Toluene 110° 1:1 2 μL 2303 ± 502 22% R 1:3 4 μL 2295 ± 210  9% 1:5 6 μL 1178 ± 282 24% 3 Methyl 101° 1:1 2 μL 2508 ± 234  9% S Cyclohexane 1:3 4 μL 2160 ± 111  5% 1:5 6 μL 1364 ± 395 29% 4 Chloroform  61° 1:1 2 μL 2075 ± 370 18% T 1:3 4 μL 2836 ± 620 22% 1:5 6 μL 1493 ± 223 15% 5 Methylene 400 1:1 2 μL 2389 f 542 23% U Chloride 1:3 4 μL 2636 ± 504 19% 1:5 6 μL 2511 ± 493 20%

In the next study various polyfunctional agents were employed using a variety of functionalities to crosslink the polymer, where the functionalities were symmetrical or unsymmetrical and the intervening chains were aliphatic or aromatic, with different functional groups as side chains. In some instances, the polyfunctional agents used for crosslinking were hydrolytically unstable, having a hydrolytically susceptible bond in the linking chain. TABLE 23 Adhesive Performance Using SELP8K, SELPOK or SELPOK-CS1 With Different Polyfunctional Agents Protein and Polyfunctional Lap Shear Buffer Ratio* Agent Tensile g/cm² Protocol SE8K 33% 2:2 Lysine 1328 + 203 V1 w/w 1:2 1212 ± 241 V2 K₂C0₃ 3:2 0:2 1161 ± 383 V3 SEOK 17% 1:2 Lysine 2143 ± 328 W1 w/w K2C03 Arginine 1176 ± 748 W2 1:1 Cysteine 741 ± 66 W3 Tyrosine  622 ± 339 W4 3,5- 339 Disulfonatocatecho SEOK 17% 1:2 Peptide  850 ± 184 X w/w K₂C03 RGRGRGKGKGK 1:1 SEOK 17% 1:2 Lysine 2901 ± 685 B w/w K₂C0₃ 1:1 SEOK 17% 1:4 cholinyl lysinate 2385 + 502 Y w/w K2C03 1.12:1 SEOK 17% 1:4 2-aminoethyl 3269 t 422 Z w/w K2C03 glycinate N,O- 1.12:1 Diglycyl ethanolamine 4:1 mixture as sulfate sal SEOK-CS1 1:2 Lysine 2196 ± 275 AB 17% w/w K2C03 1:1 SEOK-CS1 0.77:2   1,3-Propanediyl 3028 ± 392 AG 17% w/w Diglycinate K2C03 1:1 *Ratio of added nucleophilic groups to amino groups available on the protein backbone.

In Table 24, various formulations comprising either SELP8K, SELPOK, SELPOK-CS 1 are compared. TABLE 24 Adhesive Performance Using SELP8K, SELPOK, and SELPOK-CS1. K2C03 to Lap Shear Amine Amine Tensile Polymer Ratio Ratio* g/cm² % CV Protocol SEEK 17% 1:1 2:2 2854 ± 1027 36% AA w/w SEOK 17% 1:1 1:2 2143 ± 328  15% A w/w SEOK 17% 1:1 0:2 532 ± 207 39% AH w/w in 10 mM aq. Lactic Acid SEOK-CS1 1:1 1:2 2196 ± 275  13% AB 17% w/w *Ratio of amine groups derived from lysine to amine groups derived from the protein.

It is evident from the above results, that the subject invention provides for compositions which can set rapidly to provide compositions having a broad range of properties. The subject compositions can provide for strongly adhering compositions with good shear strength, the shear strength being realized within a short period of time. The subject invention also provides for compositions that are capable of filling voids or holes in tissue or otherwise augmenting the tissue. Thus, the subject proteinaceous polymers may be employed as tissue adhesives, providing physiologically compatible compositions which maintain their strength for extended periods of time, while being capable of resorption, as well as sealants, among other uses.

All publications and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.

The invention now being fully described, it will be apparent to one of ordinary skill in the art that many changes and modifications can be made thereto without departing from the spirit or scope of the appended claims. 

1: A method of repairing a defect in a body tissue, the method comprising: positioning an injector proximate to a defect in a body tissue; injecting a curable polymeric adhesive composition through the injector into a region of the defect; and allowing the adhesive composition to cure at the site of the defect, thereby repairing at least a portion of the defect. 2: The method of claim 1, wherein the curable polymeric adhesive composition repairs at least a portion of the defect by adhering to tissue during curing. 3: The method of claim 1, wherein the curable polymeric adhesive composition comprises a curable polymer and a chemical crosslinker. 4: The method of claim 3, wherein the chemical crosslinker is pre-mixed with the curable polymer before the injecting step. 5: The method of claim 1, further comprising injecting a chemical crosslinker into a region of the defect. 6: The method of claim 3, wherein the chemical crosslinker is selected from the group consisting of dialdehydes, diisocyanates, acid anhydrides, diamines and combinations thereof. 7: The method of claim 3, wherein the chemical crosslinker is hexamethylene diisocyanate (HMDI). 8: The method of claim 1, wherein the curable polymeric adhesive composition comprises a curable protein copolymer solution. 9: The method of claim 1, wherein the curable polymeric adhesive composition comprises repeating blocks of amino acid sequence. 10: The method of claim 1, wherein the curable polymeric adhesive composition comprises a network of polymer chains including repeating elastin-like and fibroin-like sequences. 11: The method of claim 10, wherein the repeating fibroin-like sequences of the polymer chains of the curable polymeric adhesive composition comprise the sequence: GAGAGS (SEQ ID NO:1). 12: The method of claim 10, wherein the repeating elastin-like sequences of the polymer chains of the curable polymeric adhesive composition comprise the sequence: GVGVP (SEQ ID NO:2). 13: The method of claim 10, wherein the repeating elastin-like sequences of the polymer chains of the curable polymeric adhesive composition comprise the sequence: GKGVP (SEQ ID NO:3), wherein the K serves as a crosslinking site. 14: The method of claim 10, wherein the curable polymeric adhesive composition is cured by chemically crosslinking the elastin-like sequences. 15: The method of claim 1, wherein the polymeric adhesive composition has a lap shear tensile strength of at least about 250 g/cm² when cured. 16: The method of claim 15, wherein the polymeric adhesive composition has said lap shear tensile strength of at least about 300 g/cm² within a cure time of about 5 to about 30 minutes. 17: The method of claim 1, wherein the polymeric adhesive composition has a lap shear tensile strength of about 100 g/cm² to about 4000 g/cm² when cured. 18: The method of claim 1, wherein the defect is a hole or void in the body tissue. 19: The method of claim 1, wherein the curable polymeric adhesive composition further comprises a drug. 20: The method of claim 1, wherein the adhesive composition is bioresorbable. 21: The method of claim 1, wherein the injector is selected from the group consisting of syringe, catheter and cannula. 22: The method of claim 1, wherein said injection is done to augment tissue mass. 23: A method of augmenting body tissue, comprising: filling a defect void in body tissue with a curable polymeric adhesive composition; and allowing the adhesive composition to cure, thereby augmenting the body tissue. 24: The method of claim 23, wherein the curable polymeric adhesive composition comprises a curable polymer and a chemical crosslinker. 25: The method of claim 24, wherein the chemical crosslinker is pre-mixed with the curable polymer before the filling step. 26: The method of claim 23, further comprising applying a chemical crosslinker to the defect void. 27: The method of claim 24, wherein the chemical crosslinker is a diisocyanate. 28: The method of claim 23, wherein the curable polymeric adhesive composition comprises a curable protein copolymer solution. 29: The method of claim 23, wherein the curable polymeric adhesive composition comprises repeating blocks of amino acid sequence. 30: The method of claim 23, wherein the curable polymeric adhesive composition comprises a network of repeating polymer chains including elastin-like and fibroin-like sequences. 31: The method of claim 30, wherein the curable polymeric adhesive composition is cured by chemically crosslinking the elastin-like sequences. 32: The method of claim 23, wherein the polymeric adhesive composition has a lap shear tensile strength of at least about 250 g/cm² when cured. 33: The method of claim 32, wherein the polymeric adhesive composition has said lap shear tensile strength of at least about 300 g/cm² within a cure time of about 5 to about 30 minutes. 34: The method of claim 23, wherein the polymeric adhesive composition has a lap shear tensile strength of about 100 g/cm² to about 4000 g/cm² when cured. 35: A method of repairing a defect in a body tissue, the method comprising: positioning an injector proximate to a defect in a body tissue; injecting a curable polymeric adhesive composition through the injector into a region of the defect; and allowing the adhesive composition to form an implant adherent to at least one tissue surface in the region of the defect, thereby repairing at least a portion of the defect. 36: The method of claim 35, wherein the implant is a hydrophilic implant. 37: The method of claim 35, wherein the curable polymer polymeric adhesive composition comprises a curable polymer and a chemical crosslinker. 38: The method of claim 37, wherein the chemical crosslinker is pre-mixed with the curable polymer before the injecting step. 39: The method of claim 35, further comprising injecting a chemical crosslinker into a region of the defect. 40: The method of claim 35, wherein the curable polymeric adhesive composition comprises a curable protein copolymer solution. 41: The method of claim 35, wherein the curable polymeric adhesive composition comprises repeating blocks of amino acid sequence. 42: The method of claim 35, wherein the curable polymeric adhesive composition comprises a network of polymer chains including repeating elastin-like and fibroin-like sequences. 43: The method of claim 35, wherein the curable polymeric adhesive composition comprises an additive. 44: The method of claim 43, wherein the additive includes an extender selected from the group of polymers consisting of synthetic polymers and naturally occurring polymers. 45: The method of claim 44, wherein the extender comprises a naturally occurring polymer including hyaluronic acid. 46: The method of claim 44, wherein the extender comprises a synthetic polymer including polyethylene glycol. 